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Liquid Chromatography of Oligomers Constantin V. Uglea Institute of Biological Research Ministry of Research and Technology and the Medical and Pharmaceutical University lasi, Romania
Marcel Dekker, Inc.
New York. Basel Hong Kong
ISBN: 0-8247-9720-5 The publisher offers discounts on this book when ordered in bulk quantities. For more information, write to Special Sales/Professional Marketing at theaddress below. This book is printed on acid-free paper. Copyright
19% by Marcel Dekker, Inc. All Rights Reserved.
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Preface
Liquid chromatography has become of late an efficient and fast tool for identifying the qualitative and quantitative composition of complex mixtures. Having been diversified by numerousprocedures, liquid chromatography is applied not only to separate mixtures madeup of small molecules, but also to determine molecular weightdistribution in oligomers and polymers. This was an important gain for specialists, since oligomersand polymers are noteasy to access by classical methodsof fractionation. Liquid chromatography is also an efficient means to control synthesis processes and to recognize the kinetics and mechanisms of oligomerization and polymerization reactions. As a result, developing liquid chromatography “homo polymericus” created the possibility of obtaining information on complex functionality in oligomers and polymers. This information is extremely useful in the formulationof new materials that provide features required by their various applications. This book focuses on two major objectives: (1) the description of the procedures used by liquid chromatography for the characterization of oligomeric mixturesand (2) the presentation of the equipment and optimal iii
iv
Preface
working conditions used to perform the separation of both well-defined oligomeric speciesand of fractions with narrow molecular weight distribution. The reader will become conversant witha complete description ofthe applications and possible performance of liquid chromatography in oligomerseparation.Moreover, Liquid Chromatography of Oligomers willbea valuableguideforthereaderonthenecessaryinformationtoestablishan optimal strategy for the practical application of liquid chromatography in the field o f oligomer characterization. Chapter 1 deals with the definition and history of chromatography and the nomenclature of oligomers. Chapter 2 discussesmolecularnonhomogeneityofsyntheticoligomers. Oligomers as well as polymers are characterized by both molecular weight distribution and nonhomogeneity of chemical composition. Functionalitydistributionisalsoincludedin the molecularheterogeneityof oligomer mixtures. Liquid chromatography of oligomers is presented in Chapter Although liquid chromatography may be performed by various procedures (thin-layer chromatography, partition chromatography, adsorption chromatography, etc.) we consider that liquid-solid chromatography represents the most important means for the study of the molecular weight distribution of oligomers. Gel permeation chromatography becamea part of liquid chromatography primarily because of its equipment characteristics. Its mechanism and performance make gel permeation chromatography a unique method with valuable applications in the chemistry of oligomers and polymers. Chapter 4 is dedicated to this method covering the theoretical basis and mechanisms; column packings (gels), calibration procedures, and applications and equipment. Liquid Chromatography of Oligomers is intended both for experts with experience in the field of oligomer and polymer synthesis and characterization and for students interested in becoming acquainted with the fascinating world of oligomers and macromolecules.
Constantin V. Uglea
Contents
Preface 1. Definition, History, and Nomenclature
iii 1
Definition I. 11. History 111. Classification of Chromatographic Methods IV.Oligomers:Nomenclature and Classification References
2. Molecular Nonhomogeneity of Synthetic Oligomers Introduction I. 11. Experimental Determination of Functionality References
21
Contents
vi
3. Liquid Chromatography I. Theoretical Basis 11. ColumnPackings 111, Column Performances IV. Choice and Optimization of Variables in Liquid Chromatography References 4. GelPermeation Chromatography
I. II . 111. IV. V. VI, VII. VIII. IX.
Index
Introduction Theoretical Basis Packings Calibration Band Broadening Non-Size ExclusionEffects Aspects ofGPC Analysis of Copolymers Selected Applications Recycle GPC and High-Performance GPC References
42 43 82 118
129 213
258 258
264 269 275 28 1 288
297 301 306 313
341
l Definition, History, and Nomenclature
Chromatography ranks among the most prominent discoveriesof our century that have greatly influenced the progress of science and technology. At present it is one of the most important analytical methods, a tool for investigating surface phenomena and solutions, well as diverse physicochemical properties of substances; itrepresents a means for thepurification and separation of substances, the basis of the automatizationof technological processes, and has several fields of application in chemistry, biology, medicine, agriculture, etc. This chapter deals with the definition of chromatographic processes, history of chromatography development, and classification of chromatographic methods. The explanation of some characteristic terms involved in the nomenclature of oligomer science is an important topic of this chapter.
DEFINITION Chromatography is a general term applied to a wide range of separation techniques based upon the sample partitioning between a moving phase, I
Chapter I
2
which can be a gas or liquid, and a stationary phase, which may be a liquid or a solid. Wide application of chromatography for theanalysis and preparative scale separation ofcomplexmixturesresulted in confusion about themeaning of the chromatographic process as such and itsapplication. Thus, in the last 50-60 years [l-61, chromatography was determined as a physicochemical process for the separation of the constituents of a mixture. From such a definition it follows that if a simple substance is injected into a chromatographic column, no chromatographic process occurs in spite of the movement of the solute through the adsorptive bed accompanied by sorption-desorption and by formation of a chromatographic band with the corresponding distribution of solute concentrations. In other words, if the aim of the process isnot theseparation of mixtures in the case of nonanalytical applications, then according to thewell-known definitions such a process couldnot be considered chromatography. For that reason a new definition of chromatography appears necessary independent of its applications. The following definition is proposed
A chromatographic process is a process based on the movement of the restricted band the substance through the adsorptive bed inthe moving phase flow and one linked with repeated elemental sorption-desorption acts. The chromatographic process occurs as a result of partitioning of the solute between two phases one of which [is] relativeto the other. Since the velocity of the movement of the solute and the position of its band on the sorbent bed in any instant is due to the velocity of the moving phase and the value of the partition coefficient, the mixture of substances having different values of the partition coefficient will be separated in the course of their movement through the adsorptive bed. The reference to a restricted band eliminates rectification and countercurrent extraction. The term Chromatography is applied both to the process and to the scientific subject matter that studies and employs this process.
HISTORY Since time immemorial humanity has competed with nature. As we have often felt powerless before overwhelming forces of nature, humanity has tried, at the beginning shyly, then quite perseveringly, to appropriate the means of nature and then to achieve its performances. Prometheus and Icarus are the first examples that come to mind. Learning from thefailures, humanity realized that ouronly chance in this encounter comes from having a profound knowledge of the mecha-
Definition, Nomenclature History, and
3
nisms on which natural phenomena are based. Their reproduction was the immediate purpose of scientific endeavors. This brings us to the inception of biomimetics, a science whose main aim isto reproduce phenomena and natural products by means of some systems able to decompose complex natural processes into simple and measurable steps. We consider that thechromatographic separations, .and especially the preparative ones, are biomimetic tentatives aimed to mimic the naturally occurring phenomena. In spite of the fact that the concept of chromatography was introduced only in the first years of this century, a convincing amount of evidence is available on the “naturaloccurrence’’ of chromatographic processes and their essential contribution to various natural phenomena. This idea is, naturally, true only on the assumption that the term chromatography is applied to the process of the migration of substance bands along a sorbent bed. In this connection it is very useful to consider the natural processes on the basis of the formalism that has been worked out foranalytical and preparative chromatography, because inthis way, we can achieve a profound understanding of these processes. On the other hand, if fully understood, some natural phenomena may also serve as an example or as a prototype forthe development of efficient methods. The migration of petroleum through rocks accompanied with the alteration of its composition is the most clearcut evidence of the “natural occurrence” ofpreparative chromatography. As has been pointedout by V. A. Sokolov [g], “the long way of petroleum in the rocks to some degree compensates for the low separating properties of such a chromatographic column; therefore, under favorable conditions, a certain separating effect will result.” Day [ g ] represents the pioneering work in this field. When proving the inorganic origin of Pennsylvania petroleum hestated that, provided the limestone is saturated with oiland some pressureis produced at the bottom, the oil migrates, the emerging product being lighter in composition and more clear than the original petroleum. Thus having percolated the heavy oil of Western Ohio (Silurgian age), a lighter product was obtained with a composition similarto thatof Pennsylvania petroleum (Devonian age). A few years later, Day [lo] proposed to use this principle for the laboratory fractionationof petroleum and its products. Day’s method can be interpretated as the frontal version of liquid-solid chromatography. However, his explanation of the results was incorrect: he assumed that the different diffusion rates of the petroleum components through the small bores between the particles of lime or clay are the main reason for the separation effect and did not mention the contributionof adsorption. Russian petroleum engineers who lived in Baku at that time thoroughly studied the problems related to the migration of petroleum and its
4
Chapter I
laboratory fractionation [ll]. As a result of this work, the Surakhamy deposit near Baku is well known to everybody active in petroleum engineering. A colorless (“white”) petroleum consisting mainlyof gasoline fractions is emerging from that deposit. A hypothesis was advanced that the petroleum from the deep levels rises to the surface through the porous medium which retards theheavy fractions. To support thistheory, one of the drilled holes was deepenedand a dark fountain of heavy oil emerged[ 121. Different authors offered various explanations of this and similar phenomena in the light of the hypothesis concerning the origin of petroleum. Nevertheless the ability of clays and other rocks to separate the oil into various fractions was accepted as an immutable fact. As was pointed out by Herr in 1908 [ 1 l ] , “nature working with an unlimited quantity of material can attain a fractionationresulting in a high purity filtrate, as can be seenin the case ofSurakhamy petroleum.” Detailed investigations ofthe percolation of oil through Fuller’s earth carried out by Herr [l11 showed that in this case the clay mainly retains aromatic compounds and compounds containing heteroatoms. On the other hand,the high-boiling paraffins andnaphthalenes pass along with the higher gasoline fractions. Thus, the overall result of the processis the bleaching of petroleum. From the modern point ofview this result can easily be explained as due to frontal liquid chromatography on the polar active solid.The composition of petroleumcan change during its migration in various ways depending on the nature of the sorbtion media: either by the preferential sorption of aromatics and substances containing sulfur, oxygen, and nitrogen, or by fractionation according to the molecular weight. The water present in the pores of the rocks acts as the modifier of the sorption properties. Various bituminous substances may also serve as modifiers. Chromatographic processes are certainly notthe onlyreason for changes in the composition of petroleum oilsduring their migration; gravitation processes, sublimation and condensation due to temperature fluctuations, etc., must also be taken into account. Nevertheless the contribution of chromatographic processes israther significant. Petroleum gases consist only of a few components, and here, itis very easy to detect the effect of separation. A number of examples are given in the literaturepointing out thechromatographic distribution of gases in the porous layers surrounding the gas and petroleum deposits [ 13-16]. Lighter hydrocarbons remain in the layeras the distance from the gas deposit increases, and only methane occurs at a distance of 175 km. Thus, the so-called halochromatographic distribution of hydrocarbons occurs around the gas (and petroleum) deposits. This is due to the combination of diffusion and sorption phenomena. The adsorbing rock slows down the diffu-
Definition, Nomenclature History, and
5
sion of gases and naturally; this slowing-down process is weakerfor lighter hydrocarbons. Sokolov [8] called this process diffusion chromatography. It is of interest to note that in 1971 a new method was proposed for gas analysis that in principle is similar to diffusion chromatography 1171. This method utilizesthe diffusion of gasesthrough the chromatographic column rather than elution. one additional factshould benoted. The high pressuresand temperatures characteristic of the depth of the earth may be considerably higher than the critical parameters. Under suchconditions the substance is a supercritical fluid with a much smaller viscosity and greater mobility than a liquid. Thus, here is a process similar to the well-known method of fluid chromatography [ 181. The differences in the amount metals in crude oils are also due to chromatographic phenomena. Thus the concentrations of vanadium, copper, and nickel in petroleum in one of the Oklahoma deposits decreases from West to East and this was accepted as one of the evidences for the migration of petroleum from theWest [ 191. Besides this, it has beennoted [ 191 that theincrease of the distance of migration is followed bya decrease in the concentration of the I3Cisotope. These regularitiesin combination with the dataconcerning the hydrocarbon composition of petroleum make it possible to describe their “history,” the direction of their migration, and-depending on the place and depth of the deposition and onthe type of the rocks servingas the medium for themigration -to make certain predictions. Chromatographic processes must also be taken into account when choosing underground gas deposition. Either exhausted gas deposits or water strata should be selected. However,it is necessary in the firstcase to removehydrogen sulfide (to avoid deterioration in the quality of the pumped gas) and in the second case to dry the stratum. These processes may be covered with the same formalism as chromatographic separation [20,21]. Scientists investigatingthe formationof ores and distribution of various metals in them, concluded that in these cases chromatographic processes are very significant [22]. The ions of iron, copper, nickel, cobalt, and other metals were stated to move in silica and alumina gels due to diffusion. Thus, there is a combination of diffusion and ion exchange. Chromatographic phenomena are importantin natural biological processes. This particularly refers to the process of breathing. For example, the absorption of oxygen by blood hemoglobin in the lung as well as the absorption (bothreversible and irreversible) ofvarious harmful impurities are to a certain degree chromatographic processes. The utilization of hemoglobin in analytical gas chromatography is a logical extension of this natural
6
Chapter 1
biologicalprocess and indeed, this hasbeendescribed in two papers [23,24]. In these investigations,blood, coated on a solid support, served as the stationaryphase for the separation of oxygen from the otherinorganic gases and its determination. The examples outlined in these paragraphs indicate that chromatography is a natural process and is always realized in nature. Thus, just as in other fields of knowledge, we must regard nature as our teacher, perceive its laws, refine and further develop the natural processes, and apply them to the tasks we are facing. The discovery of “synthetic chromatography” is generally creditedto Tswett, a Russian scientist. Brief information concerning his life has been published in some papers [25-271. He was born on May 14,1872, in Asti, a little town in Italy. His mother, Maria De Dorozza, was an Italian born in Turkey and educated in Russia. His father, Semen Tswett, was a Russian from Chernigov (Ukraine), where the family name of Tswett had been known for a longtime. M. S. Tswettwas educated in Switzerland (in Lausanne and Geneva). In 1891 he entered the University of Genevaand in 1893 obtained his baccalaureate. In 1896 he presented his doctoral thesis in botany entitled “Investigations on the Physiology of Cells.” In the same year he moved to Russia where he lived first in Simferopol, then worked for a very short time in the Botanic Garden of Odessa University, and in late 1896 he left it forSt. Petersburg. Here Tswett worked at theBiological Laboratory, became a reader in botany at a school for women attached to it, and began to work on the preparation ofhisMaster’s thesis at the Botanical Laboratory of the Russian Academy of Sciences. In 1900, upon the recommendation of several prominent scientists, Tswett was given a membership of the St. Petersburg Society ofNatural Scientists. In 1901 Tswett prepared his Russian Master’s thesis entitled “A Physico-Chemical Study of the Chlorophyll Grain. Experiments and Analysis” which he dedicatedto thememory of his father. In January 1902 Tswett moved to Warsaw, where at first he held a modest positionat theuniversity, that of a supernumerary laboratory assistant, and later,of an instructor atthe Chair of plant anatomy and physiology. In the same year he was promoted to an assistant professorship and qualified to lecture. Here at the library of Warsaw University worked a Czech, Helena Trusevich, who Tswett married in 1907. In 1908 he was accepted on the staff of the Polytechnic Institute andcompleted his Doctorate thesis, published two years later as Chromophyllsin Plants and Animals W .
During his sojourn in Warsaw he traveledaround Europeto acquaint himself with the status of scientific research work and the methods of teaching botany in higher educational institutions, particularly in the Bo-
Definition, Nomenclature History, and
7
tanical Institutes of Berlin, Kiel, Amsterdam, Leyden, Delft, Brussels, and Paris. In 1915 when the German Army approached Warsaw, Tswett moved with Polytechnic Institute to Moscow and in 1916, to Nizhny Novgorod. Finally, in 1917, he was appointed Ordinary Professor and Director of the Botanic Garden at theUniversity of Yuriev (now Tartu, Estonia).After the town had been occupied by the Germans in February 1918, he left Yuriev for Voronezh where hewas professor of Botany at the University until his death resulting from heart disease on June26, 1919. While still workingin Petersburg on his Master’s thesis, Tswett persistently sought a physical method that would permit the separation of a mixture of chlorophyll pigments beingsure of the complexity ofits composition. In Warsaw hecontinued his experimentsand finally madehis discovery. His paper “On a New Category of Adsorbtion Phenomena and Their Application to Biochemical Analysis” was presented at the meeting of the Biological Department of the WarsawSocietyof Natural Scientists on March 8-21,1903 [29]. Although the principles of the method had been already laid down in his Master’s thesis, it is this date thatshould be considered the birthday of chromatography, rather than theyear 1906 mentioned by manyauthors. Tswett started with static experiments on the absorption of the pigment on a strip of filter paper from a solution in an alcohol-petroleum ether mixture. Upon drying, the paper strips were dark green in color; treatment withpetroleum ether produced a yellow solution, and when treated with petroleum ether to which alcohol has been added the solution became dark green, while the strip of paper was discolored. Later he used particles ofa sorbent instead of paper, also under static conditions, and the next stage wasfiltering through a bed of the sorbent placed at the top of a filtering funnel, i.e., under dynamic conditions. It was then easy to observe a difference in color according to the height. Later he usedtubes (columns) filled with a sorbent. Tswett began the experiments on the separation of pigments by using the frontal mode; later he discovered the development (elution) version of chromatography and at once appreciated its advantages. The only question that is not mentioned in his first communication is the term chromatography, whichby no means prevents this work from being consideredthe firstfundamental research inchromatography. In connection with the new term chromatography, the dataavailable on thepeculiar features of Tswett’s character make quite plausible the suggestion made by Purnell “It would be nice to think, that Tswett, whose name in Russian means color, took advantage of the opportunity to indulge his sense of humor.”
8
Chapter I
In his two subsequent papers published in 1906, three years later than his first report, Tswett already introduced the term chromatography. In the first of these two papers he writes about his discovery in a vivid, picturesque language: Like light rays in the spectrum the different components of a pigment mixture are separated on the calcium carbonate column and then can be qualitatively and quantitatively determined. I call such a preparation a chromatogram, and the corresponding method chromatographic method. It is very essential that in his publication Tswett has pointed out that the method is equally suited for theseparation of colorless substances. Tswett widely used the chromatographic method not only to separate a mixture and to prove that it consistsofmany components, but also for quantitative analysis; he contemplated the possibility of introducing reference (marker) components into themixture of facilitate identification. He was the first toemploy chromatography as a preparative method to produce individual compounds; he was the first to use a change in the properties of the mobile phase (gradient elution) during the chromatographic process. He also pointed out the need for a spectral study of the compounds in the adsorbed state. Tswett developed the apparatus for theprocess of liquid chromatography, realized for the first time the possibility of carrying out chromatographic processes in a vacuum or under pressure, summarized the recommendations for the preparation of effective columns, and was the first to use both micropacked and preparative columns and theinverse flow ofthe mobile phase in the column; he drew attention to the necessity of accounting for the simultaneous occurrence of adsorption processes and purely diffusion phenomena in the column. He carried out separation of substances both by their partial elution and by complete elution from the column. Apart from developing the fundamentals of the method and extensively using it to solve many problems that are complicated even at the modem level of science, he also introduced many of the basic conceptsand terms of the new method, including the name of the method, chromatography, development, displacement, chromatogram, etc. Tswett imparted a new, deeper meaning to the adsorption method than was known before. In particular, thelater development ofpaper chromatography is to a considerable degree the result of extending the general relationships discovered by Tswett to theparticular case of adsorbtive separation of a mixture on paper strips. He has to a certain measure also foreseen the advent of thin-layer chromatography (TLC) by showing the
Definition, History, and Nomenclature
9
analogy between the properties of a paper strip and those of a calcium carbonate layer used for thechromatographic analysis ofsolutions. This detailedexamination of Tswett’s discoveries makes us fully agree with Zechmeister [33], who wrote, “M. Tswett isthe trueinventor of chromatography in all ofits fundamental aspects.” One of the characteristic features in the history of development of science and techniques, chemistryand biology in particular, is the fact that the trend and rate of development dependto alarge extent on theutilization of certain methods of research and their efficiency. This has been stressed among others by Tswett himself: “Every scientific advance is an advance in method” [28]. In the 18th century it was crystalyzation that wasbeing developed for nonvolatile substances and then turned into multistage crystalization; in the 19th century, for volatile substances, evaporation that had been known for centuries, was transformed into multistage distillation; in the 20th century sorbtion and extraction of volatile and nonvolatile compounds was converted into multistage and continuously highly efficient processes. Chromatography is one of them. The importance of many outstanding discoveries is not always appreciated at first. Further developments often begin only after a considerable period of time has elapsed. The duration of such a latent period is a measure of the degree to which the discoverer has advanced ahead of his contemporaries. The latent periodof chromatography lasted about 25 years, only a small number of various applications of the method being reported during this time. Thus after 1911, DhCrC [34], in Switzerland, and Stoklassa, in Czechoslovakia [28] systematically used chromatography; in the United States this method was used somewhat later by Palmer [35]. Other scientists usingchromatography in this latent period include Goward [36] and Lipman [37] who were concerned withthe study of extracts from flowers and the separation of rhodoxanthine and xanthophyll, and Bird and others were close to the development of gas chromatography (GC) [38]. And yet chromatography did not advance significantly during this period. This is due partly to the negative comments of Wilstatter who warned against chemical reactions of the pigments with the adsorbents. However, the mainreason was the absence of a genuineneed for the method. The latentperiod lasted until 1931 when Lederer, Kuhn, and Winterstein [39,40] demonstrated the usefulness of the method. Since this time, the growth of chromatography has been continuous; newer and newer versions have been developed and applications in newer and newer fields demonstrated. However, based on the results of studies of old literature [41-461 some experimentsperformed in the pre-Tswett period should bementioned.
10
Chapter I
Thus it would seem that the earliest results in this field are obtained by Runge who used in 1834 a radial method for conducting the process of separating salts and organic substances [47,48]. Then, in 1851, Schonbein and Goppelsroeder [49-511 started aseries of investigationson the so-called capillary analysis which consists of the separation of zones on the paper strips. Tswett was well acquainted with these works and wrote: “Goppelsroeder devoted himself since 1861 to the practical development of Schonbein’s idea with an astounding patience and accumulated an enormous amount of observations” [28]. He also noted the work done in 1851 by Cohn who obtained a radial chromatogram similar to Runge, with three rings whenevaporating drops of solution of “phycocyan”[52]. Another group of studies was devoted to separation on asorbent bed. It would seem that in this case it is bestto begin with the words of Tswett, whocitingSachsse,wrote [28], “The adsorptive properties ofsoilwith respect to salts were known already to Aristoteles since he pointed out the conversion of sea waterto potable water when makingit to pass through a layer of earth.” Williams [45] referred to the work of Thomson and Williams who were approaching separation on a column with an adsorbent long before 1850. Subsequently, the results of Read (1893) [53] should be mentioned, who observed some changes in the composition of a solution of salts when filtered through powdered kaolin. The results of Day in 1897 also belong here [54]. He observed the clarification of oil upon being filtered through Fuller’s earth. In 1900 S. K. Kvotka received a patent for a method of fractionating petroleum by filtration through porous media. Similar results were obtained by Englerand Albrecht [S]. In all of these cases, the separation by adsorption have been carried out by the simplest versions of frontal analysis. However, in spite of their unquestionable value,usefulness, and interest, none oftheseproposed methods are able to evolve into thechromatography that we extensively use today and is basedon theworks of Tswett. Then in the late 1930s and early 1940s chromatography began to evolve. The foundation of thin-layer chromatography (TLC) was laid in 1938 by Izmailov and Schreiber [56] and later refined by Stahl [57,58] in 1958. The remarkable work of Martin and Synge in 1941 [59], not only revolutionized chromatography but in general setthe stage for thedevelopment of gas chromatography and paper chromatography [60]. In the late 1960s more and more emphasiswas placedupon developing liquid chromatography as a complementary techniqueto gas chromatography. High performance liquid chromatography (HPLC) or high pressure, high speed, and modern liquid chromatography has evolved from this effort. Advances in both instrumentation and column packings occurred rapidly that it was difficult to maintain a state-of-the-art expertise. Indeed,
Definition, Nomenclature History, and
I1
even today the technique is rapidly maturing and is rapidly attaining an equal stature with other investigation techniques. During the early 1970s the advantages of liquidchromatography were really just beginning to draw attention to a wide audience. Revolutionary improvements in equipment, materials, techniques, and application of theory have brought liquid chromatography to what Snyder and Kirkland [61] have aptly called “modern liquid chromatography.” Resulting from the phenomenal interest and continued growthinhigh performance liquid chromatography, an analyst during the last decade has seen value added to the already existing advantages of convenience, accuracy, speed, and the ability to successfully deal with very difficult separation problems. It will hardly come as a surprise to the reader that the large majority of the references cited inthis book about HPLC of oligomers will come from the past 10 or 15 years. To effect most of these difficult separations has required the resources of modern liquid chromatography. Both classical LC and TLC have long histories. In the late 1950s TLC started to emerge as a simple, low-cost, relatively efficient means of separating less volatile components of organic mixtures. HPLC surplanted GC in the late 1960s and early 1970s for chromatographing nonvolatile compounds. Just as chromatography (an efficient means of fractionation) has widely replaced fractional crystallization, has HPLC increasingly replaced classicalliquid column chromatography. Applications of the latter have not grown nearly as fast as HPLC in recent years simply because HPLC is a more advantageous way to accomplish the same objectives.The goals of maximum efficiencyin a minimum time haveshifted the emphasis from traditional liquid chromatography techniques into modern HPLC and GC, including small-bore column technology. Even TLC, while preserved in muchits traditional form, hasprogressedsuch that manyhigh-performance TLC (HPTLC) applications have appeared [all. It is interesting and useful to contrast and compare liquid chromatographic techniques. Modern HPLC is fast, very efficient, relatively expensive,easily automated, and useful for analytical aswell as preparative needs.Classicalcolumn chromatography islessexpensive, but ismuch slower, less efficient, and not as easily automated. Itis also useful for either preparative or analytical work. Both paper and TLC are closely related in technical aspects: the details of development, sampleapplication and detection are much the same. They differ in the nature of the stationary phase, with paper having that phase anchored to the carrier while TLC has the sorbent loosely spread or fixed on a rigid (glass) support. The traditional borderlines between these two techniques have blurred, but TLC has appeared to be more widely retained for general laboratory applications. TLC is often indispensable
Chapter I
12
tool in many laboratories. It is easy to learn, comparatively inexpensive, fast, convenient, versatile, uses standardized stationary phases (prepared plates), and is reasonably efficient. HPTLC can offer equivalent resolution in reduced time or improved resolution in equivalent time (compared to normal TLC). TLC is attractive especially to those laboratories having low capital budgets. It is especially useful wherea large number of samples are to be examined and where the components of interest are relatively easily separated. TLC bridges a gap between traditional column liquid chromatography andmodern HPLC.
CLASSIFICATION OF CHROMATOGRAPHIC METHODS The state of aggregation of the two phases, the mechanism of separation process, the shape of the adsorptionisotherm that characterizes the elementary separation process and some specific workingconditions are thebasic criteria that areapplied in the classification ofchromatographic methods. Taking into account the characteristics of the two phases,chromatography may be dividedinto liquid chromatography (LC) and gas chromatography (GC). According to this classification paper chromatography (PC), thin layer chromatography (TLC), liquid-liquid chromatography (LLC), steric exclusion chromatography or gel permeation chromatography (SEC or GPC), affinity chromatography (AC), and ion-exchange chromatography are the most important procedures of LC. According to the mechanism and drive forces that act during the elementary process of separation, chromatography maybedivided into adsorption chromatography, partition chromatography, ion-exchange chromatography, and SEC or GPC. The shape of the chromatographic peak is determined by the shape of the isotherm specific to the elementary separation process. From this point of view, chromatography may be a linear or nonlinear process. In the case of a linear isotherm, the chromatographic peak (elution curve) is represented by a normal distribution curve while the nonlinear isotherm determines an asymmetric elution curve. This asymmetry is proportional to the degree ofnonlinearity of the isotherm. Some experimental details determine the characteristics of the chromatographic process. Dependingon thepressure, the chromatographic separation may bea high pressureor a low pressure process. Depending on the structural characteristics of the oligomers, among the chromatographic methods LSC and SEC are preferably used for the characterization of molecular nonhomogeneity of synthetic oligomers.
Definition, History, and Nomenclature
13
IV. OLIGOMERS:NOMENCLATUREAND CLASSIFICATION IUPAC defines an oligomer asa substance composed of molecules containing a few of one or more species of atoms or groups of atoms (constitutional units) repetitively linked to each other. This definition does not specify an absolute degree of polymerizationor molecular weight that distinguished an oligomer from a polymer, but it does further state that the physical properties of an oligomer vary with the addition or removal of one or a few of the constitutionalunits from molecule. This structure-property definition is perhaps the most meaningful definition of oligomer. The term oligomer originates from Greek words oligo = few, and meros = part andwas first used by Burckard et al. [62]. Burckardalso was originator of the term oligopeptide [63]. Telechelic oligomers, macromonomers, and prepolymers are three other terms used in oligomer science. The term telechelic polymer was proposed in 1960 by Uraneck et al. [64] to designate relatively low molecular weight macromolecules possessing two reactive functional groups situated at both chain ends. The term originates from the Greek words telos = far and chelos = claw, thus describing the molecule as having two clawsfar away from each other, i.e., at theextremities of the chain, able to grip something else. An oligomer can be consideredto be a telechelic if it contains at least one reactive end group which can react selectively to give a bond with another molecule. Dependingon functionality (which must be distinguished from the functionality of the end group itself), telechelics can be classified as mono-, di-, tri-, or polytelechelics [65]. The original definition of telechelic needs some additional comments in connection with end groups reactivityand the influence of experimental conditions upon this reactivity. This means that apolymer may be telechelic under certain experimental conditions, but nottelechelic underothers. Theoretically all oligomerscan be considered to be telechelic provided one can find a reaction that is selectivefor thechain ends ofthe polymers, provided a given reagent is able to distinguish the end groups from the main chain. This interpretation leads to a more generalized interpretation. Thus atelechelic may be any oligomeric species that contains at least one “informational site” capable of a selective replyagainst an external stimuli in a given experimental system. A second problem that is encountered when looking for a general definition of the telechelic is the “functionality” of the telechelic. We have to make a distinction between “functionality” of oligomeric speciesand the functionality of the end group itself. Not only the functionality of the end
14
Chapter I
group itself is of considerable importance. A telechelic oligomer may have more than two reactive end groups because they are branched or have a star-shaped structure. These polymers can be designated as tritelechelic, tetratelechelic, or polytelechelic. Of course, the oligomers that possess only one reactive functional end group have been called monotelechelics or semitelechelics. In defining the nature of a telechelic oligomer or polymer, an important question is if such a compound having different functionalend groups can be regardedas telechelic. Supposewe can make a linear polymer having one hydroxyl endgroup andone amino end group. Undoubtedly, this polymer would give a number of possibilities for constructing interesting welldefined polymer structures. The condition is, however, that all molecules have indeed one hydroxyl and one amino end group. If only the average amount of hydroxyl and amino end groups is one for each polymer molecule, it will not be possible to use this compound to produce a well-defined structure. Keeping this in mind, the classical polycondensation polymers, obtained from two bifunctional monomers, cannot be regarded as telechelic, although they possess two end groups, unless their synthesis has been conducted in such a way that the end groups are the same for each individual molecule presentin the mixture. For example, a linear polyester having two hydroxyl endgroups or two carboxyl endgroups is a telechelic polymer, but a linear polyester witha distribution of molecules having two hydroxyls, one hydroxyl and one carboxyl, and two carboxyls is not a telechelic polymer. Onthe other hand, linear a polyesterin which all macromolecules have one hydroxyl and one carboxyl end group may again be considered as a telechelic. It will be monotelechelic for reactions involving either the hydroxyl or the carboxyl; it will be ditelechelic if it reacts at both extremities. Thus, thetelechelic concept hasa pragmatic sense. This statement has no reference about chemical structure oftelechelic, but itrepresents the behavior of this “material expression’’ in a given experimental system and especially its capacity to create previsible and welldefined macromolecules. More precisely,this concept contains the possibility of a given oligomeric species to be involved in the transport of an amount of information as precursor of a di- or tridimensional macromolecule with regulatedstructure. A very important requirement of telechelic oligomers is their perfect terminal functionality, i.e., the average number functionality of a ditelechelic oligomer must be 2.0, that of a tritelechelic must be etc. Most research to date concentrated on defining and developing clean systems, i.e., systemsthat reproduce and conveniently yield perfect average over a desirable molecular weight terminal functionality (1.O or 2.0 or range and molecular weightdistribution.
15
Definition, Nomenclature History, and
A large amount of data has been generated with terminally functionalized polyisobutylenes (PIB) prepared by the inifer method [66-681. Quantitative derivatization of these new telechelic oligomers gave riseto a whole new family of unique materials. A most promisingnew development concernsthe synthesis of phenoltelechelic PIBs. These materials are structurally closely relatedto bisphenol A and therefore the linear product is called bisphenol-PIB. The versatile terminal phenol function allows further derivatizations. The chlorine telechelic products can be quantitatively dehydrochlorinated and in this manner olefin-telechelic oligomerscan be obtained [69]. The latter materials can be quantitatively further derivatized to other telechelics. For example, sulfonation of the terminal olefin groups by acetyl sulfate withsubsequent neutralization yielded new “endless”ionomers [70,71].
Hydroboration followed byoxidation of olefin-telechelicPIBs yielded hydroxy telechelic oligomers [68], which have been used in a great variety of subsequent transformations. Indeed, one most promising lead is the synthesis of PIB-based polyurethanes by reacting HO-telechelic liquids with various isocyanates inview of the synthesis of “model” or “perfect” network (i.e., a network in which the molecular weights between crosslink points are the same). Finally, here are few thoughts about nomenclature. The nomenclature” can beused for ditelechelic oligomers. It uses the usual prefix substituent names for the functional end groups, followed by the name of oligomer. For example:
-NH2
H0 H 0 -OH H0
: a-hydroxy-polyethylene : a,o-hydroxy-polyethylene : a-hydroxy-w-amino-polyethylene
The oligomer withthe following structure H0
H0 has been termed byGoethals [72] trihydroxytelechelic polyethylene. The prefix terminated nomenclature or prefix telechelic such as “carboxy-terminated polyethylene”or “carboxy-telechelic polyethylene”can be used to designate a class of polyethylene having carboxylic end groups, but the description is in fact incomplete becauseit does not say if it is a mono-, di-, or polytelechelic.
16
Chapter I
For complex endgroups, the prefix name isput between brackets and preceded bymono-, bis-, or tris-; examples:a,o-bis(phydroxypheny1)polyethylene. The concept of prepolymers, which can be transformed into final products, with well-specified properties by reaction of end-standing functional groups with multifunctional coupling agents was not new. early as 1937, Otto Bayer [73] used this concept in polyurethane chemistry based on hydroxy-terminated oligomers. The functionality of the reactive end groups itself is another important parameter that plays an important andprimordial role in the potential uses of the telechelic oligomers. The usual telechelic oligomers havemonofunctional end groups, i.e., end groups that can form one bond with another functional group. Other end groups may be unequivocally bifunctionalor multifunctional. Such groups, if they can participate in a polymerization reaction, are of special importance because copolymerization of oligomers containing such end groups with low molecular weight monomers leads to graft copolymers (for monotelechelics) or to polymer networks (for di- or polytelechelics). Such telechelic oligomersare “macromolecular monomers’’and are commonly calledmacromonomers or macromers. Therefore, macromers have to be considered as a special class of telechelics, the classical monomers being bifunctional monotelechelic. The term macromonomer or macromer was introduced by Milkovich in 1974 [74]. However, Bamford et al. [75,76] had demonstrated in 1958 that graft copolymers could beprepared by copolymerizinga small monomer with the terminal double bond of poly(methy1methacrylate) prepared by radical polymerization under conditions in which the termination reaction is mainly disproportionation [771. The great interest in telechelic oligomers resides in the fact that such molecules can be used, generally together with suitable linking agents, to carry out three important operations: Chain extension ofshort chains to long ones by means of bifunctional linking agents Formation of networks by use ofmultifunctional linking agents Formation of block copolymers by combination of telechelics with different backbones These conceptsare of great industrial importance since they form the basis of the so-called liquid polymer technology exemplified by “reaction injection molding” (RIM). Great interest has also been shown bythe rubber industry because the formationof a rubber is based on network formation. In classical rubber technology, this is achieved by the crosslinking of long chains that show high viscosity. The classical rubber technology, therefore,
Definition, Nomenclature History, and
17
requires an energy-intensive mixingoperation. The use of liquidprecursors, which can be end-linkedto the desired network, offers notonly processing advantages, but in some cases, also better properties of the end product. Finally, the development of “thermoplasticrubbers” has furthermore stimulated the industrial interest in telechelic polymersthat arepotential starting materials for such thermoplastic rubbers. The use of telechelics in epoxy resins, polyurethane, and polyesteracrylates production represent another example the great interest in the field of synthesis and characterization of oligomers.
REFERENCES 1. Keulemans, A. I. M., Gas Chromatography, Reinhold Publ. Corp., New York, 1957. 2. Bayer, E., Gas-Chromatographie,Springer-Verlag,Berlin-Gotingen-Heidelberg, 1959. 3. Schay, G., Theoretische Grundlagen der Gas-Chromatographie, VEB Deutscher Verlag der Wissenschsften, Berlin, 1961. 4. Dal Nogare, S. and Juvet, R. S., Gas-Liquid Chromatography. Theory and Practice, Interscience Publishers, New York, London, 1962. 5. Golbert, K. A. and Vigdergauz,M. S., Treatise of Gas-Chromatography, Khimija, Moscow, 1967 (in Russian). 6. Vigdergauz, M. S., On thedefinition of a chromatographic process, Chromatographia, 5, 107, 1972. 7. Kholkin, Yu. I., Remarks, Prikl. Khim., 2,9, 1970 (in Russian). 8. Sokolov, V. A., Processes of formation and migrationof petroleum and gas, Nedra, Moscow, 1965, pp. 178-186 (in Russian). 9. Day, D. T.,Proc. Amer. Phil. Soc., 112, 1897 (cited in ref. 8). 10. Day, D. T.,La variation des caractkes des huiles brutesde Pennsylvanie et de
11. 12. 13. 14. 15. 16.
YOhio, Intern. Congr. Petroleum, Notes, Memoires et Documents, Paris, 1900, pp. 53-60. Herr, V. F., Trudy Bakinskogo OtdeleniyaRusskogo Tekhnicheskoy Obshchestva, 22,21, 1908; 22,39 1908; 25,81, 1911 (cited in ref. 8). Kalitzki, K., Proc. ofthe Geol. Committee, St. Petersburg, 30,585,1911; cited in ref. 8 (in Russian). Nagy, B., The sedimentary strata as a chromatographic column, General Petroleum ChemistrySymposium, New York, 1959. Nagy, B., Review of chromatographic “plate” theory with reference to fluid flow in rocks and sediments, Geochim. Cosmochim. Acta, 19, 1, 1960. Nagy, B. and Wourms, J. P., Chromatographic separations and concentration of organic compounds in sediments, Bull. Geol. Soc. Am., 35, 1662, 1958. Roper, W. A., Doscher, T., and Kobayashi, T., Evidence of chromatographic effect during flow of gasesthrough oil-field cores, J. Petroleum Tech., March 1958, p. 15.
18
Chapter I
17. Khokhlov, V. N., Okhotnikov, B. P., and Zhukhovitskii, A. A., Diffusion chromatography, Zavod. Lab., 37,533 1971 (in Russian). 18. Klesper, K., Corvin, A. H., and Turner, D. A., The influence of migration upon the composition of petroleum, J. Org. Chem., 27,700, 1962. 19. Silverman, S. R., Migration and separation of oil and gas fluids in substractive environments, Amer. Assoc.of Petroleum Geologists, Geology of Fluid Symposium, Midland, January 30, 1964. 20. Shtof, M. D., Trudy Kuibyshev N.I.I.N.P., 40,242,1968(in Russian). 21. Karimov, M.F. and Odegov, A. I., Petroleum Refinerand Petroleum Chemistry Synthesis, Petroleum Inst. Ufa, 1974,p. 293 (in Russian). 22. Ritchie, A. S., Chromatography in Geology, Elsevier, Amsterdam, 1964. 23. Gil-AV, E. and Herzberg-Minzky, Y., Chromatographic phenomena in biological processes, J. Amer. Chem. Soc., 81,4749, 1959.
24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41.
Zhuknovitskii, A. A.,Anew stationary phase for liquid chromatography, Khim. Tekhnol. Topliv. iMassel, 1972,No. 6,p. 7 (in Russian). Richter, A. A. and Krasnopolskaja, T. A., M. Tswett-A short Biography in Adsorbtion Chromatography Analysis, Izd. Akad. Nauk, Moscow, 1946, p. 229 (in Russian). Hesse, G. and Weil, H., Michael Tswett’sfirst paper on chromatography,M. Woelm-Eschwege, 1954. Sakodynskii, K. and Solujanov, P., Gas Chromatography, Niitechim, Moscow, 1967,p. 116 (in Russian). Tswett, M., Chromophyll in plants and animals, Izd. Karbasnikov, 1910 (in Russian); cited in ref. 27. Tswett, M., Trudi Varshavskovo Obshestva Estetsvoi spitalei otd. biologii, 14, 20, 1903 (in Russian); citedin ref. 27. Parnell, H., Gas Chromatography,J. Wiley BE Sons, New York, 1962. Tswett, M., Ber. deutsch. Bot. Ges., 24,316, 1906; cited in ref. 41. Tswett, M., Ber. deutsch. Bot. Ges., 24,384, 1906; cited in ref. 41. Zechmeister, L. and Cholonsky, L.,Principles and Practiceof Chromatography, New York, 1943;cited in ref. 42. Dhtrt, C. and Vegezzi, G., C. R.Acad. Sci., 2,399, 1916; cited in ref. 42. Palmer, L. S., Carotinoids and related Pigments, New York, 1922;cited in ref. 42. Goward, K., Biochem. J., 18,11 14, 1924; cited in ref. 42. Lipman, Th., Compt. Rend.,182,867, 1926; cited in ref. 42. Berl, E. and Wacherdorf, E. Z.,Angew. Chem., 37,298,1930;cited in ref. 42. Kuhn, R. and Lederer, E.,Ber. deutsch.Bot. Gm.,64,218,1931;cited in ref.41. Kuhn, R., Winterstein, A., and Lederer, E., 2 . Phys. Chem., 197, 147, 1931; cited in ref. 41. Weil, H. and Williams, T., History of chromatography, Nature, 166, 1O00,
1950. 42. Faradane, J., History of chromatography, Nature, 167, 120, 1951. 43. Weil, H. and Williams, T., Early history of chromatography, Nature, 167, 906,1951. 44. Zechmeister, L.,Early history of chromatography, Nature, 167,405, 1951.
Definition, Nomenclature History, and 45.
19
Williams, T., History of chromatography, Anal. Chem., 25,531, 1953.
46. Heines, S. V., Evolution of chromatography, J. Chem. Educ., 46,315, 1969. XWZ, 65,1834; cited in ref.44. 47. Runge, F.F.,Annalen der Physik und Chemie, 48. Runge, F. F.,Farbenchemie, 111, 1850; cited in ref. 44. Schonbein, C.V., Naturforsch. Verh. Basel, 3,240, 1861; cited in ref. 42. Schonbein, C., J. Chem. Soc., 33,304, 1878; cited in ref. 42. Goppelsroeder, F., Verh. Naturforsch. Basel, 3,268, 1861; cited in ref. 42. Kohn, A., 2.Wiss. Zool., 3,264, 1851; cited in ref. 42. Read, L., Proc. Chem. Soc., 9,123,1893; cited in ref. 42. Day, D.,Znd. Techn. Petr. Rev., 3,9, 1900; cited in ref. 46. Engler, C. and Albrecht, E. Angew. Chem., 14, 865, 1904; cited in ref. 46.Izmailov, N. A. and Schreiber, M. S., A new method of separation for the organic compounds,Farmatsiya, 3,15,1938 (in Russian). 57. Stahl, E., A new version of adsorbtion chromatography, Chemiker Ztg., 82,
49. 50. 51. 52. 53. 54. 55. 56.
323,1938. 58. Stahl, E., Theoretical aspects of thin layer chromatography, Pharmazie, 11, 633, 1956. 59. Martin, A. J. P. and Synge, R. L. M., Theory of chromatography, Biochem. J., 35, 91, 1941.
60. Consden, R., Gordon, A. H., and Martin, A. J. P., Equilibrium theory of
61. 62. 63. 64. 65. 66. 67.
chromatography, Biochem. J., 38, 224, 1944; for refs. 56-60 see Liteanu, C., Gocan, I., Hodisan, T., and Nascu, A., Liquid Chromatography, Academic Editorial House,Bucharest, 1974, p. 26. Snyder, L. R. and Kirkland, J. J., Introduction to Modern Liquid Chromatography, 2nd ed., J. Wiley & Sons, New York, 1979, Ch. 1. Burckard, H., Bohn, E., and Winkler, S., Ungesatige Derivate von Gentiobiose und Cellobiose, Berichte, 63B, 989, 1930. Burckard, H. and Griinert, H., N-methansulfonyl derivate von amino-sauren und oligopeptiden, Ann., 545, 178, 1940. Uraneck, C. A., Hsien, H. L., and Buck, 0. G., Telechelic polymers, J. Polymer Sci., 46, 535, 1960. Goethals, E. J., Telechelic polymers: synthesis and applications, CRC Press, Boca Raton, 1987. Kennedy, J.P.and Marbchal, E., Cationic Polymerization, John WileyInterscience Publishers, New York, 1982. Fehervary, A., Kennedy, J. P., and Tiidos, F., New telechelic polymers and sequential copolymers by polyfunctional initiator-transferagents (inifers). IV. Chain transfer, molecular weight distribution and NMR study of telechelic a,w-Di(tert)chloropropylisobutylene, J. Macromol. Sci., Chem., AIS, 215, 1980.
Ivan, B., Kennedy, J. P., and Chang, V. S. C., New telechelic polymers and sequential copolymers by polyfunctional initiator-transferagents (inifer). VII. Synthesis and characterization ofa,w(dihydroxy)polyisobutylene, J. Polymer Sci., Polym. Chem. Ed., 18,3177, 1980. 69. Kennedy, J. P., Chang, V. S. C., Smith, R. A., and Ivan, B., New telechelic polymers and sequential copolymers by polyfunctionalinitiator-transfer
68.
Chapter I
20
70.
71.
72.
73.
74. 75. 76. 77.
agents (inifer). V. Synthesis of a,o-Di(isopropeny1)polyisobutylene and a-tertbutyl-w-isopropylpolyisobutylene,Polymer Bull., I , 375, 1979. Kennedy, J. P., Storey, R. F., Mohajer, Y.,and Wilkes, G. L., New polyisobutylene based model ionomers. I. Synthesis and characterization, Abstracts, IUPAC MACR0’82, p. 905, Bucharest. Kennedy, J. P., Storey, R. P., Mohajer. Y.,and Wilkes, G. L., Mew polyisobutylene based model ionomers. 11. Structural-property relationship, Abstracts, IUPACMACR0’82, Bucharest, p. Nuyken, 0. and Pask, S. D., Telechelics by carbocationic reactions in Telechelic Polymers: synthesis and applications,Goethals, E. J., ed., CRC Press, Boca Raton. 1987, Ch. 5. Bayer, O., Die neue methode gestatted Zum ersten male kunstoffe mit praktisch beliebigen eigenschaffen und eindentich klarem chemischen aufbau herzustellen, Angew. Chem., 76,553, 1947. Milkovich, R. and Chiang, M. T.,U.S. Patent, 3,786,116, 1974. Bamford, C. H.and White, E. F. T., Synthesis of a new copolymers based on poly(methy1methacrylate), Trans. FaradaySoc., 54,268, 1958. Bamford, C. H.,Jenkins, A. D., and White, E. F. T., The termination reaction in the copolymerization process, J. Polymer Sci., 34,271,1959. Bamford, C. H. and Jenkins, A. D., Disproportionation reactions in the copolymerization of methyl methacrylate with other vinyl monomers, Nature, 176, 78, 1955.
Molecular Nonhomogeneity of Synthetic Oligomers
INTRODUCTION Molecular species forming oligomeric mixtures differ through their molecular weight, chemical composition, and functionality. If molecular weight and chemical compositionare two characteristics equally involvedin polymer and oligomer chemistry,the functionality is a more specific parameter for the monomer and oligomer chemistry. The concept of functionality was introduced by Kienle [ l ] and today is understoodto mean the positions per oligomeric species capable of reacting under specific conditions. Let us define functionality F by
F = -N/2 l/Mn
- NM,,
”
2
where N is the total number of functional groups per gram of sampleand M,, is the number average molecular weight the of sample [2]. Functionality can assume all values from zero upward, including fractions, but chain molecules are formed onlyif the value is at least two. 21
Chapter 2
22
The above interpretation represents only a pragmatic understanding as long as the functionality is not an absolute property of a functional group, but always has to be considered in relation to the reaction partner and, sometimes, withreaction conditions. The following examplesillustrate the influence of monomer or oligomer structure as well as of the reaction conditions upon the value of functionality. A lone isocyanate group, -NCO, in a monomer is, for example, monofunctional with respect to a lone -OH group if both groups are present at about thesame concentration. Therefore, to form polyurethanes with the urethane group -NH-CO-0-, diisocyanates must react with diols. With an excess of isocyanate groups, however, the urethane groups can convert to allophanates:
+ -NH-CO-0-
-NCO
"NH"C0
I
-N-CO-0-
(2)
Since two isocyanategroups react withone hydroxyl group to form allophanates, the -NCO group is semifunctional. With polymerization initiators (chain growth kinetics), however, the isocyanate group is always bifunctional:
n N=CO
-(N-CO-)"-
I
I
R
R
The chemical structure of the resulting macromolecule, moreover, will be decided not only bythe functionality of the groupcapable of encatenation, but also by the functionality of the molecule. The strained heterocycle of lactams is bifunctional with respectto cationic initiators. However, neutral and protonatedpolymer amide groups can also take part in the disproportion, viz.:
+
I " C O
-
CO
+
1
-
+
-CO
CO +
-
I-
Molecular Nonhomogeneity
Oligomers Synthetic
23
The new polymer cation can, in turn, initiatelactam polymerization again. These side reactions increasethe mean functionality of these base units to more than two. The mean functionality of the monomer, however, can also be smaller than the sum of the functionalities of the groups contained in its molecule. For example, in the Diels-Alder condensation of a bisdiene with benzoquinone (where no byproduct is formed, yet the polymer is formed through a stepwise kinetic process), the total functionality of the bisdiene in chain formation is two perunbranched macromolecule:
Carothers derived a simple equation relating the degree of polymerization (DP) to the extent of reaction p , where p is defined as the fractionof functional groups that have reacted at time t. Thus 1 - p is the fractionof groups unreacted. If it is assumed that there are No number of moleculesat the start,then the number of remaining unreacted moleculesis
N = No(1
-p)
(7)
The average number of repeatingunits in all molecules at any stage in the reaction is the original number of molecules dividedby the remaining number of molecules:
-
o DP = NN The expression for W in terms of Carothers equation:
reaction conversion is known as the
According to this limiting equation, oligomers of M = 20 to 50 are formed for conversions of 95 to 98%. Very few reactions in organic chemistry can be forcedto andbeyond 98%, yet this requirement is the first characteristic that should be considered when itis proposed to apply a new reaction to a step-growth polymerization.In order to obtain step-grown oligomers ofM equal to 200, the fractional conversionpshould be 0.995. The general equation for the formation of a linear polymer by the step reaction of bifunctional reactants A and Bmay be writtenas follows: nA
+ nB
A(BA),-IB
(10)
Chapter 2
24
The probability of finding a repeating unit AB in the oligomer chain is p and the probability of finding n - 1 of the repeating units is p'"'. Since the probability of finding an unreacted molecule of A or B is p - 1 , the probability (P,,)of finding a chain with n repeating units (BA),, is
P,, = ( 1
- p)pI-'
(11)
Hence, the probability of the totalnumber of repeating units (BA),, is N,, = N ( 1
- p)p'"l
(12)
where N is the number of molecules in the mixture after the reaction has occurred to the extent p . Since N = No(1 - p). Equation 12 becomes N,, = No( 1
- P)~P'"
(13)
The corresponding weight-average molecular weight distribution W,, may be calculated from therelationship W,, = nN,,/No:
The number-average molecular weight weight M, are as follows:
a,,and weight-average molecular
- mN0 M,, = N and
where m is the molecular weight ofthe monomer. The index of polydispersityM J M , for the most probable molecular weight distribution is then "
Thus, as mentioned above, when p = 1, i.e., for a total conversion, the index of polydispersityfor themost probable distribution for step-reaction polymers is 2. The limitation on is usedto advantage when it is desired to obtain polymers with lower molecular weight by step-growth polymerizations. It is obvious that the value of p may be reduced by using an excess of one ofthe reactants or by adding a calculated amount of a monofunctional reactant (quenching the reaction before completion or adding a stoichiometric excess of one reactant is not economical).
m
Molecular Nonhomogeneity
of Oligomers Synthetic
25
If the number of monofunctional molecules present in the reaction mixture is Ni in addition toNo difunctional molecules A-B, the relationship (eq. 9 ) between the fractionalconversion ofeither A or B groups in the must be modified to take into account the effect of this monofunctional, polymer-chain termination:
DP =
+ Ni/No 1 - p + NJN0 1
For example, if the monofunctional derivative is present to the extent of 1%, eq. 18 predicts that a reaction conversion 98% will yield a polymer with a DP approximately 34 instead 50 as seen above. Assuming that the step-growth polymerization involves AA and BB monomers and that the B groups are present in excess, the stoichiometric imbalance defined bythe ratior
determines the number of unreacted functional groups after the reactions reaches the extent p , as shown below:
and
T N B = ( 1 - p r ) N : = ( 1 - p r )N:
(21)
where N t and NE are the number of A and B functional groups, respectively, in the initial reaction mixture, and N A and N B are the number of these groups at various stages of reaction. The total number of chain ends is the sum of N A and N B , and the total number of chains, N,, half the number of chain ends, is
= A2(
1
+ -r1 - 2 p ) N t
The totalnumber of repeating units distributed among these chains,N,, is the number of monomer molecules present initially: N,
= -1A T :+ -1N : 2
2
=
2
(23)
Chapter 2
26
Dividing the number of repeat units by the number of chains, one obtains the number average degree of polymerization:
DP =
l + r 1+r-2p
Considering eq. 23, for a 1 Yo excess of BB, i.e., r = a of 50 is attained at reaction a conversion of98.5%. The Carothers [ 3 ] equation as originally derived contained a factor, to account for the effect of monomers having more than two functional groups on the degree of polymerization.In this case, is the averagefunctionality, i.e., the number of functional groups per monomer moleculefor all types of monomer present:
where Ni and& are the number of molecules and the functionality of the ith component in the reaction mixture, respectively. The original number of functional groups in the reaction mixture is then No? and the number of functional groups that have reactedis 2(N0 + N being the total number of molecules present in the reaction mixture at an extent of reaction p . Therefore
Elimination of Nfrom eqs. 26 and 8 gives the modified Carothers equation:
When the average degree offunctionality of 2, this equation reverts to the previous form given by eq. 9. The modified Carothers equation demonstrates how sensitive step-growth polymerization for is thepresence of small amounts of polyfunctional monomers which can act as branching or crosslinking sitesin the growing chain. For a fixed extent ofreaction, the presence of multifunctional monomers in an equimolecular mixture of reactivegroups increases the degree of polymerization. Conversely, for the same mixture, a lesser extent of reaction isneeded to reach a specified with multifunctional reactants than without them. If the number of functional groups is unequal, this effect works in opposition to the multifunctional groups. For example, in eq. 10, if there is one trifunctional monomer in every ten original A monomer molecules, then f = 2.1 and a conversion of 95% will result in a polymer
Molecular Nonhomogeneity
of Oligomers Synthetic
27
having a of 200 instead of 20, as mentioned above for a stoichiometric mixture of bifunctional partners. Carothers attempted to correlate the concept of functionality with the structure resulting polymers. He concluded that linear polymers are formed only when the monomers are bifunctional, and if the functionality is higher than 2, gelation takes place and a three-dimensional structure is formed. Korshak [4]showed, however, that many tri-, tetra-, andhigher functional monomers can form linear polymers. Korshak consideredthat there are three types of factors which determine the relation between monomer functionality and polymer structure. The first factor, illustrated by the reaction of glycerol (f = with phthalic anhydride (f = 2), is determined by the monomer structure. The reactivity of functional groups is variable. Only at temperatures above 18OOC are glyphthals formed. At lower temperatures, linear polyesters are formed since the polycondensation involves primarily the -CH20H groups of glycerol, which are much more reactive than secondary CHOH hydroxyls. The second type of factor refers to the influence of experimental conditions. The reactivity of functional groups might dependon the nature the catalyst used, the proportionof monomers,the nature of the solvent, and thetemperature. For example, in the reaction of formaldehyde (f = 2) with phenol (f = not all of the active hydrogens are equally active. Under acid conditions, the quinoid structure
>
is stabilized as a reaction intermediate favoring the para additions of the protonated formaldehyde molecule. There are also indications that the reaction of one position alters the reactivity of others, the reactivity depends on the extent of reaction as well. Low molecular weight polymers with chain capped by phenol repeat units (known as A-stage resins, novolacs, or resole prepolymers)are formed when the ratioof CHzO toC6H50H is less than unity. The reactionis either acid or base catalyzed, and branching is uncommon at this stage. When the reaction is carried out under basecatalysed conditions and with a formaldehyde/phenol ratio greater than unity, a final crosslinkedpolymer(called a C-state resin or resite) is formed. The influence of solvents is illustrated by the reaction of "diamino-4,4'-dihydroxy-diphenylmethane with carborane dicarboxylic acid: in common solvents, a three-dimensional product is obtained, while the addition of tributyl amine favors the formationof linear polymers[4]. The third type refers to some favorable arrangements of functional
Chapter 2
28
groups in monomer molecules, and can be illustrated by the so-called ortho effect [5]. This phenomenon explainsthe formationof linear polymers with heterocycles in the main chain from tri- and tetrafunctionalmonomers. A typical example is the two-step preparation of an aromatic polyimide bythe reaction of pyromellitic anhydride with aromatic diamines. In the first stage, polyamic acid is formed in aprotic solvents (dimethylformamide, dimethyl-sulfoxide):
150%
Polyamic acid
Bonding occurspredominantly at thepara position; there is relatively little attack at the meta positions. In order to avoid crosslinking reactions, the solid content of the solution is restricted to 10-15070 and the yield to 50%. In the second stage, water is eliminatedat 300OC. The step-growth reactions in the early stages of the process yield oligomers which react to form polymers. The course of further conversion depends not only on the amount of functional groups in monomers, but also on thearrangement and activity of functional groups in oligomer molecules. It is therefore necessary to extend the concept of functionality from monomers to oligomers. Moreover, side reactions may alter the original functionality of monomersor thatof oligomers. Consequently, the functionality should be defined as possible functionality, q5po, or theoretical functionality, i.e., the highest number of reactive functional groups derived from themolecular structure, oras practical functionality, &, i.e., the number of functional groups capable of reacting under given conditions. The latter can change with reaction conditions (temperature, concentration of monomers, nature of catalyst, type of solvents, etc.). Based on these definitions, it is possible to express the functionality of a given monomer in step-growth polymerizations in terms of relativefunctionality, qiR, which is the ratio of to This new quantity characterizes the reactivity of both parent monomers and resulting oligomers. Usually, &,rand 4R2 1. When = 2, the resulting oligomersor polymers are linear and if4h 3, three-dimensionalstructures are formed.
&.
Molecular Nonhomogeneity
Oligomers Synthetic
29
Other types of functionality include the number-average functionality, &,and the weight-average functionality,&, which are defined by the following relations:
+ +Po2 + +P03 +
+Pol
"=
*
*
-
cZN, +poi
"
Nl+N2+N3+---
and
-
+Eo1
=
6PolNl
+ 4kO2 + + + +Po82 + +P083 +
' *
c c
&oi
(31)
+PO&
where and Ni represent the possible functionality and the numberof moles of species i , respectively. The oligomers used in industrial processes as starting materials are characterized both by molecular weightand functionality distributions. In other words each oligomeric sample is, in fact, a mixture of oligomeric species characterized by different molecular weights and functionalities. The concept of functionality distribution was introduced by Entelis et al. [5a]. This concept may be used in the characterization of the behavior of oligomers during the processing as well as for the determination of final properties of the products. The functionality distribution may becharacterized by number-average functionality, which can be determined bythe following relation:
an
where is the number average molecular weight the of oligomeric sample and M, represents the equivalent molecular weight of the repeatable unit. In turnM, may be defined by the following relation:
M, = M,
1m/s
(33)
where M, and S represent the molecular weightand concentration (in weight percent) of an oligomeric speciesin a given oligomeric mixture. Since the physical properties of polymer networks dependon the crosslink density, and thecrosslink densityis largely determined bythe oligomer reactive-groups,equivalentweight, and the averagenumberofreactive groups per molecule, the functionality is of greatest importance to those working with these materials. Functionality is usually calculated by dividing molecular weight by equivalentweight (relation The determination of molecular weight in the range lo3 - lo4 is, however, subject to an uncertainity of at least * W O even when sure that one is working with a pure material. A need exists for amore precise method.
Chapter 2
30
The preceding relations contain no information specific for the evaluation of the functionality distribution. For example, = 2 represents an ideal value for a difunctional oligomeric mixture but this value is also characteristic to a oligomeric mixture which contain equal amounts of monoand trifunctional species. We can avoid uncertainty using 4,. These two averages allow usto approximate the width ofthe functionality distribution curve of the analysed oligomeric mixture. The value of $,, is influenced bythe existance ofthe unfunctionalized or cyclicspecies in the oligomericsample.This fact determines a high degree of uncertainity in the experimental determination ofthe 4,J4,, ratio. In this case the functionality distribution curve is determined by chromatographic methods. Functionalized oligomersform multicomponent systems within which the molecular species are distinguished through their molecular mass and functionality. In turn, functionality distribution maybedivided in two components: quantitative and qualitative. Quantitative functionality distribution represents the amounts of functional groups per molecular species. This distribution gives no information about the position and the repartition of the functional groups along the molecular species. These details are revealed by the qualitative functionality distribution. Unfortunately, the experimental determination ofthe qualitative functionality distribution represents eventoday a debated problem of oligomer chemistry. given oligomeric species can be affected simultaneouslythe by molecularweight and functionality distributions. Only in a fewcasesfine organic synthesis give rise to well-defined functionalized oligomers. In practice, the experimental determination of molecular weight distribution in oligomeric samples is directly influencedthebychemical composition variation and functionality distribution ofthe given sample[a-1 l]. Let us consider one oligomeric species i which is characterized by a given functionality4. In this case
+,,
"
and
Molecular Nonhomogeneity
of Oligomers Synthetic
31
where and represent number and weight average molecular weight of an oligomeric species withfunctionality$ Mm is molecular weightof a functional group. From the relations 34-37 result (MW/M,,),= M J M , whenM,/M,, = 1 and M,, B 2flM,. "
"
"
II. EXPERIMENTALDETERMINATION OF FUNCTIONALITY Besides chromatographic methods, other physical and physicochemical methods may be usedin order to determine the value of averagefunctionality?,, (relation 32). Since @,, and Recan be determinedby direct methods, it is obvious thatf,, may be also determined by direct methods. Osmometry, ebulioscopy, vapor pressure osmometryand other methods may be usedfor the determination of G,,.On the other hand, equivalent molecular weight ae(relation 33) is determined by the known analytical methods [ 12,131. Thus esterification with aceticor phthalic anhydride is used for thedetermination of the concentration of hydroxylic groups while acidictitration and reaction with HBr are used for the determination of the content amidic and, respectively, of epoxy groups the analyzed samples. The content of double bonds is determined bythe bromine index method. Indirect determination of the functionality is based on gel point and crosslinking densitymethods.
A. The Gel Point Method The Flory-Stockmayerpolycondensation theory [ 14-19] for complex, branched reactants predicts the extent of reaction at which weight average properties of the product, such as the weight average molecular weight, become infinitely large. This critical reaction extent is defined as the gel point. The determination of the gel point may be achieved by using equations connecting the extent ofreaction at thegel point with the functionality of the reactants. This method could be reversed and the functionality calculated from the extent of the reaction at the gel point. In order to do this, the equation connecting the various factors must bein terms of two average functionalities, one for each type of reactant, each functionality capable of taking on any positive value. Flory limited his theory to systems in which only one of the reactants had a functionality greater than 2 [ 15-18], whereas Stockmayer extended the theory of three-dimensional condensation polymers to reactions between molecules with two different functional groups but no restricted functionality distribution. The so-called Stockmayer gel equation resulting from this theory is
Chapter2
32
shown belowfor anAB-type polycondensation, a reaction where groups of type A can react only withgroups of typeB. =
- 1)-'(g, -
l)-' where PAand PErefer to the respective fractions of groups A andB reacted and f w and g, are weighted average functionalities (referred to as effective functionalities) of react A andB, respectively, defined as (PApB)wl
(fw
and
Here Ai is the number of moles of reactant A bearing i functional groups and Bi is the number of moles ofreactant B bearing j functional groups. Stockmayer's gel equation is useful for the prediction of gel point or for the determination of effective functionality, provided three basic assumptions of the gel equation are met, equal reactivity of like groups, absence of cyclization, and of side reactions. For certain systems, such as carboxy-terminated polybutadiene-polyol reactions, these assumptions appear to be fulfilled, as has been shown by Strecker and French [20,21]. In their application, Strecker and Frenchconsider that the A groups (e.g., carboxyl groups) can react only withB groups (e.g., hydroxyl groups) andvice versa. At every time ofreaction equal amounts of reactive groups of type A and B must havereacted. By transformation ofeq. 38 one can write
and
where r is the ratio of the total number of B groups initially present to the total number of A group initially present. According to eq. 42, in a test for functionality it is necessaryto know only the functionality of the crosslinking agent, the ratio of reactants, and the extent of reaction of either of the reactants at the gel point. The value
Molecular Nonhomogeneity
of Oligomers Synthetic
33
Tw.
obtained is a weighted averagefunctionality, If the spread in functionality is small,fW will be closeto the?". In thecase of carboxy-terminated polybutadiene-polyol reactions, the determination of unreacted carboxyl groups at the point was carried out principally byinfrared methods. The titration methods may be equally used in this respect. Some work was done to see whether titration of carboxyl groups with standard base was sufficiently accurate for functionality measurements. Onedifficulty with the titrationmethod liesin the time required to withdraw a viscous aliquot from the reaction mixture. The mixture is viscous when approaching the gel point that a minute or two may be required to remove a sample large enoughto titrate. In that time the reaction has proceeded sufficientlyto introduce a significant error. Phenolic antioxidants are often present in commercial oligomers. These react with a base and may or may not react with epoxidesor aziridine crosslinking agents. To remove this uncertainity the oligomers must be purified. At best the titration method cannot be considered as accurate as the infrared method. The last method needs a correct calibration in order to determine the true content of carboxylic end group during the condensation reaction with phenols. In the case of polyisocyanated, the basic requirements of Stockmayer's gel equation cannot usually be meet, mainly because of the frequent occurrence of like groups of unequal reactivity and the need for relatively dilute systems to detect the gel point [22]. However, a useful form of Stockmayer equations can be retained for the calculation of the true effective functionality of such reactants. 1.
Influence of Functional Groups of Unequal Reactivity
When a polycondensation reaction isallowed to proceed to completion under nonstoichiometricconditions, for example groups of type A being in excess, PAis equal to the initial mole ratio of B to A groups, and PB= 1. Thus, there will be a critical initial ratio of the reactive groups for which gelation will coincide with the completion of the reaction. In this case, Stockmayer's gel eq. 38. simplifiesthen to the following form
where (PA)gcl is the critical initial ratio of B to Agroups. The corresponding equation for theconverse case( B groups in excess) is
The eqs. 43 and 44 have been determined by Fogiel [22] usingthe criterion of gelation given by Case [23].
Chapter2
34
2. Effect of Cyclization The problemofring formation in polycondensation reaction hasbeen treated theoretically by Jacobson and Stockmayer [24]taking intoaccount an original mixture of reactants consisting of A,, A,, . . , Ai moles of reactants of type A bearing, respectively, 1, . . , i functional groups and B,, B,, . . . , Bj of reactant of type B bearing, respectively, 1,2, ., j functional groups. All unreacted groups ofthe same kind are assumed to be equally reactive. Let rnbe the probability of forming an n-unit ring, where a single unit is defined to contain two groups of each type along the backbone forming the ring. Consider a bond -[AB]- picked at random from thereacted system. The objective is to compute the probability for the recurrence of the bond without cyclization (partial propagation expectation P;). After summing up over all monomers and ring sizes (total propagation expectation), gelation will occur when P = 1. The probability that B of the -[AB] - bond belongs to Bj monomer is pi; the probability that any of the (j 1) groups of type B has reacted with a group A belonging to Ai, which isnot a part of the molecule chosen at random,is
.
.
..
-
n'
p p B ( j- 1)P ( 1
- nC rn) =l
(45)
where n' is the number of units present in the chain selectedat random. The probability of any of the ( i - 1) groups reacting with any B group other thanthose derived from the same molecule isthe partial propagation expectationpb, viz. n'
P;J
=ppB(j
2
- I)Pi( - n=l r n ) P A ( i
- l)
(46)
Summing piJ over all species and ring sizes and equating the sum of unity yields the gel point
or
For a small extent of cyclization, the gel equation can be approximated to
35
MolecularNonhomogeneityof Synthetic Oligomers -1
m
(pApB)gel
=
(1 - c
rn)
(fw
-
l ) -'(gW
-
l ) -I
(49)
l
The problem remains to compute the value of Cz=lrnof the re1ation 49. According to Jacobson and Stockmayer [ M ] the ratio of the number of rings n units (R,,)to the number of chains of n units (C,) is
where B=(%) is a parameter the reaction conditions, V denotes the total volume of the system, v is the number of chain atom per unit, and b is the effective bond length. Assuming a small amount of cyclization
where c is the concentration of reactive groups one of the reactants in moles perliter. Summation of over all ring sizes yields
The infinite series m
is a well-known Reimann I function which has the value of 1.341. For a given polycondensation system, allparameters may be combinedto give 2 5 r n = k-
c Substituting this value into eq. 49 yields Stockmayer's gel equation [l41 modified to account for ring formation, viz. n=l
The method of gelpoint has been verified using various oligomeric systems. Thus, the value o f f wwas determined for hydroxyl or carboxyl terminated oligobutadienes [25,26], polypropylene glycols [27], and tiokols [28].
Chapter 2 Table 1 Average Functionality o f Liquid Tiokols (solidifier: manganese dioxide) Functionality of linear part of oligomer
ii?, 1
- = B”
2470 2170 2350 2500 2600 3500 2060 2300 2050
S3
2.38 2.40 2.45 2.58 2.53 2.57 2.33 2.30 2.40
2.40 2.41 2.44 2.50 2.50 2.55 2.20 2.20 2.20
2.20 2.35
2.45
-
2.37 2.23 2.30
‘Calculated from -SH determination data, bCalculated from fractionation data. Source: Ref. 25.
The variation of functionality in the case of industrial tiokols is presented in Table 1. Table 2 gives some results on functionality of carboxyl terminated oligobutadienes obtained by using Epon X-801with a functionality of as curing agent. The value of functionality of the resin is approximately the same, whether calculated from the epoxide reaction or
Table 2 Weight Average Functionality of Carboxyl-Terminated Oligobutadienes Reaction Glycerol Reaction Epoxide
6
COOH react. time COOH Gel react. time Gel (mm 290 242 152 136 152 178 Source: Ref. 20.
(min)
(qo)
2.40 2.37 2.95 2.38
24.0 26.5 24.5 19.0
59.8 60.2 50.3 60.2
2.40 2.38 2.97 2.38
2.24
18.5
64.2
2.22
04
Molecular Nonhomogeneity
Oligomers Synthetic
37
from the glycerol reaction. Other characteristics concerning various oligomeric systemsare presented in Tables In theory, the number of average functionality, g,, can be determined from theaverage molecularweight M,, (corrected for water) and theequivalent weight E,, according to the equation
The determination of functionality of high molecularweight polyols bythe molecular weight method is rather unsatisfactory due to a relatively high experimental error ( *5%), but particularly due to a very strong effect of potentially present low molecularweight inert materials. The gel point method, on the other hand,is insensitiveto the presence of inert materials and it is precise to about1070. Moreover weight average and number average functionalities of conventional polyols usedfor flexible foams will differ by only 4% in the most unfavorable case (50/50 equivalent ratio of diol and triol). Therefore, the gel point method appears to be suitable for thedetermination of number, as well as weight average functionalities of conventional polyols. In Table 5 functionalities of the polyols are compared with respectto the method used. Even though the water content has been excluded in
Table 3 Number and Weight Average Functionalityof Oligoesters (curing agent:hexamethylenediisocyanate) Glycerol To
content, Oligomer 2.26Oligoesterb 2.17
M,, j/j,,
0.75 1S O 1280 1.so 2.241490 1.21 3.22 2.65 1890 3.00 Oligobutadienpolyol 1.63 3.43 - 2.10 2300 1.43 3.96 - 2.77 2275 2.86 1730 1.51 5.15 3.41 2000 2.44 5.61 - 2.30 2400 8.10 - 2.80 2800
j~j,,
1680
-
2.22 1.042.31 2.40
1.07
1.61 4.61
2.89
'Determined by gel point method. bCopolyester based on adipic acid, diethylenglycol, glycerol, and hydroxy terminated oligobutadiene. Source: Ref. 25.
02
Chapter 2
38
Table 4 Number and Weight AverageFunctionality of Carboxyl Terminated Oligobutadiene and Copolymers of 1,3-Butadienewith Acrylonitrile (curing agent: epoxyline-5) Gel Oligomer Oligobutadiene 2.09 220 2.05 0.99 2.06 280 1.00 2.07 260 0.98 2.04 240 1.03 2.00 210 1.02 1.97 320 Copolymer 1,3-butadieneacrylonitrile Copolymer 1,3-butadienemetacrylic acid
2.08 2.07 2.08 1.94 1.93
3690 3230 3110 3120 2570 1760 3130 430 3280 3230 360 2520 2310 2310
386 1.08 0.98 1.03 - 2.26 - 2.95 - 2.95
1.90 2.13 1.98 2.10 2.01 2.01
2.06 2.08 2.04 4.74 5.94 5.93
Source: Ref. 25.
the calculation of molecular weight, the functionality of these materials is appreciably lower by the molecular weight method than by the gel point method, the lattergiving results closerto the expected functionalities.
B. CrosslinkingDensity Method The accuracy with whichthe functionality of a given oligomer can be measured dependson the accuracy with whichnumber or weight average molecular weight can be measured. Table 5 Functionality ofSelected Polyols Used for Flexible Foams Material Polyester “triol” (“Voranol” CP-3OOO) Polyester ‘Yriol” (Witco “Fomrez” 50) Polyester (Witco “Fomrez” 52)
g,’
a,,
E,“
2073 2.672.08 996 2810 2.672.561087 2265 2.312.02 1120
‘Equivalent weight. bDeterminedby the following relation: g, = M,/,!?,. aetermined by gel pointmethod. Source: Ref. 22. ”
g,”
Molecular Nonhomogeneity
Oligomers Synthetic
39
From an examination of available test methods and their limitations for number average molecular weight measurements, vapor pressure mometry was selected as the most suitable method for the low molecular weight range (1000-5000). Vapor pressure osmometry(VPO) is a thermoelectric differential vapor pressure technique for determining M,, of oligomers. The thermoelectric methods has significant advantages in speed and in small sample size. The basis of the thermoelectric method is the measurement of the small temperature difference resulting from a differential mass transfer between droplets of pure solvent and oligomer solution maintained in an atmosphere of solvent vapor. It is true that molecular weight measurements can be seriously lowered by the presence of low molecular weight impurities, notablyresidualsolvent and antioxidants. There are other factors, though, which must be considered:the possibility of oligomer-oligomerassociation which leads to anapparently higher molecular weight, and the phenomenon of oligomer-solvent interaction. If a polymer is formulated at a one-to-one ratio of reactive groups and complete reaction is obtained, the crosslinking density, X,, as moles of branch points per gram can be obtained and is givenby the following relation:
where n = number of different reactants; i = the individual reactants, values 1 to n; f = functionality of the reactants known for all ingredients except oligomer and not to exceed in value; W = weight fraction of ingredients; E = equivalent of ingredients. The possibility of using the critical conditions of gel formation and concentration of internodal chains of a network to calculate the?,, and?, has been analyzed by Entelis l] using as an example the system involving the copolymer of tetrahydrofuran andpropylene oxide, 1,4-butanediol, 1,1,1-trimethylol propane and 2,4-toluylenediisocyanate. The effecthas been shown ofthe reactivity ofinitial reagents, temperature and concentration of a catalyst on the value of the $,, and f, determined by indirect methods. In this instance, the change of relative capacity of reaction of reactants under the influence of temperature has been determined. The value of determined functionality was also influenced bythe mechanism of oligomerization reaction. Both influencesare materialized by a twenty percent variation of the $,, and ?, values. The differences between ?,, and f, values obtained by indirect methods or by determination of chemical composition may determined also by the other three additional factors: the
40
Chapter2
uncertainity of functionality determination, the difference between chemical and effective functionalities and by the incertitude of molecular weight determinations. The differences between chemical and effective functionalities appears mainly when the value of monomer functionality is higher than Another shortcoming of indirect methodsis the fact that these methods do not take intoaccount the unfunctionalized species. The application of indirect methods is limited to the monomers with functionality lower than However, these methods are suitable for the determination of effective functionality of various oligomeric systems. In this manner some predictions are possible concerning the structure and physicochemical properties of the end products.
REFERENCES 1. Kienle, R. N., Kinetics polycondensationprocesses, Znd. Eng. Chem.,22, 590,1930. 2. Min, T. L., Miyamoto, T., and Inagaki, H., Determination of functionality distribution in telechelic prepolymers by TLC, Rubber Chem. Technol., 50, 63, 1976. 3. Carothers, W. H.,Polymers and polyfunctionality, Trans. Faraday Soc., 32, 39, 1936. 4. Korshak, V.
V., Dependence of polymerstructure on monomer functionality, Acta Polym., 34,603, 1983. 5. Korshak, V. V., Thermoplastic Polymers, Nauka, Moscow, 1972, 211(in Russian); a) Entelis, S. G., Functionality distribution in synthetic oligomers systems, J. prakt. chem., 313,484, 1971. 6. Uglea,C. V., Hemicellulose fractionation, Makromol. Chem., 175, 1535,
1974. 7. Simionescu, N., Uglea, C. V., and Feldman, D., Uber die polydispersitat ‘der methylcellulose, Cell. Chem. Technol., I, 199, 1967. 8. Uglea, C. V., Simionescu, N., and Feldman, D., Contribution au fractionnement des copolymbres. I. Copolymbres acrylonitrile-acetate de vinyle, Rev. Roum. Chim., 13,949, 1968. 9. Feldman, D., Uglea, C. V., and Simionescu, N., Contributions au fractionnement des copolymbres. 11. Copolymbres ternaires acrylonitrile-acbtate de nyle-alphamethyl styrene, J. Polymer Sci., A-l, 7,439, 1969. 10. Uglea, C. V., Lupu, V., and Sgndescu, F., Contribution B la caracterisation des copolmbres.V. Influence des conditions experimentalessur les resultats du fractionnement, Rev. Roum. Chim., 16,1399, 1971. 11. Adams, H.E., Ahad, E., Chang, M. S., Davis, D. B., Franch, D. M., Ager, H. J., Law, R. D., and Simkins, J. J. P., A cooperative molecular weight distribution test,J. Appl. Polymer Sci., 17,269, 1973. 12. Baczek, S. K.,Anderson, J. N., and Adams, H. E., Methods of functionality determination intelechelics, J. Appl. Polymer Sci., 19,2269, 1975.
Molecular Nonhomogeneity
ofOligomers Synthetic
41
13. Schneko, H., Degler, H., Dongowski, H., Caspary, R., Angerer, G., and Ng, T. S., Synthesis and characterizationof functional diene oligomers in view of their practical application, Angew. Makromol. Chem., 70,9, 1978. 14. Stockmayer, W. H., Molecular weight distribution in synthetic polymers, J. Polymer Sci., 9,69, 1962. 15. Flory, P. J., Molecular size distribution in three dimensional polymers. I., J. Amer. Chem. Soc., 63,3083, 1941. 16. Flory, P. J., Molecular sizedistribution in three dimensional polymers. II., J. Amer. Chem. Soc., 63., 3091, 1941. 17. Flory, P. J., Molecular size distribution in three dimensional polymers. III., J. Amer. Chem. Soc., 69,30, 1947; IV., ibid., 63,3096, 1941. 18. Flory, P. J., Molecular size distribution in three dimensional polymer units, V., J. Phys. Chem., 46, 132, 1942; Flory, P. J., Molecular size distribution in three dimensional polymer units. VI. Branched polymers containing A-R-Bf., type units, J. Amer. Chem. Soc., 74,2718, 1952. 19. Stockmayer, W. H., Molecular distribution in condensation polymers, J. Polymer Sci., 11,424, 1953. 20. Strecker,R.A. H. and French, D.M., The determination of reactive-group functionality from gel point measurement,J. Appl. Polymer Sci., 12, 1697, 1%8. 21. French, D. M. and Strecker, R.A. H., Functionality and observed versus predicted gel points, J. Macromol. Sci. Chem., AS, 893, 1971. reactions of polyiso22. Fogiel, A. W., Effective functionality and intramolecular cyanates and polyols, Macromolecules, 2, 581, 1969. various 23. Case, L. C., Theoretical interpretation of functionality distribution in oligomeric systems, J. Polymer Sci., 26,333, 1957. 24. Jacobson, H. and Stockmayer, W. H., Intramolecular reaction in polycondensation. I. The theoryof linear systems, J. Chem. Phys., 18, 160, 1950. 25. Valuev, V.I., Shlyakhter, E. G., Erenburg, E. G . , and Poddubnyi, I. Ia., Study of the functionality distribution of various oligomers, Vysokomol. Soedin., AI4,2291, 1972. 26. Consaga, J. P., The determination of functionality distribution in carboxyl terminated oligobutadienes, J. Appl. Polymer Sci., 14,2157, 1970. 27. Evreinov, V. V., Ol’kov, Yu. A., Baturin, S. M., and Entelis, S. G . , Indirect methods for determination thefunctionalities of oligomers, Vysokomol. Soedin., A20,2146, 1978. 28. Prom. SK, 1976, No. 3, p. 15 (Russian). 29. Entelis, S. G . , Evreinov, V. V., and Kuzaev, A.I., Reactive oligomers, Khimia, Moscow, 1985, Ch. 3. 30. Ol’kov, Yu. A., Lugovoi, V. B., Baturin, S. M., and Entelis, S. G . , Kinetics of three-dimensional polymerization and the effect of monofunctional molecules on the properties of cross-linked poly(etherurethane) elastomers, Vysokomol. Soedin., A14,2662,1972. 31. Ol’kov, Yu. A., Baturin, S. M., and Entelis, S. G., Reactivities of functional groups ofcomponents and theirinfluence on thethree-dimensional polymerization. Kinetics and the properties of cross-linked poly(ether-urethane)s, Vysokomol. Soedin., A15,2758, 1973.
Liquid Chromatography
During the early 1970s the advantages of liquid chromatography(LC) were really just beginning to draw the attention of a wide audience. Revolutionary improvements in equipments, materials, techniques,and the application of theory have brought LC to what Snyder and Kirkland have aptly called Modern Liquid Chromatography [l]. Liquid chromatography is now a mature analytical technique that is based on a well-developed theoretical background and as a consequence is carried out with fairly efficient LC equipment. The high level of performance achievable by LC today, however, is the direct result of over two decades of careful study into the basic theory of chromatographic separations. Liquid-solid chromatography (LSC) is the oldest form of the four basic modes ofLC (ion-exchange, gel permeation,partition, and LSC). The first person who was able to explain correctly the phenomena taking place during the movement of substances along a sorbent bed was Michael S. Tswett [2]. Using these phenomena, he created a remarkable analytical method, showed its wide scope, and named not only the tech42
Liquid Chromatography
43
nique itself but also the process and the branch of science dealing with it. On March M. S. Tswett presented at a meeting of the Biological Section ofthe Warsaw Society ofNatural Sciences a preliminary communication “On a New Category of Adsorbtion Phenomena and their Application to Biochemical Analysis’’ In this lecture, he reported on the first part of his experiments aimed to separate plant pigments. Tswett systematically tested a very large number of solids to check the possibility of using them as adsorbents; he definitely understoodthe nature of adsorbtion and already took an important step forward by being ableto have spatial separation of several zones on the adsorbent. Although Tswett didnot describe in hismethod(whichwas not yetfinalized)as“chromatography” (this name was first used in in his two well-known papers his investigations were already in a well advanced stage. Thus, we can safely characterize his communication as his first paper on chromatography. When Michael Tswett began to perform chromatography, he used a polar support as a stationary phase and a nonpolar solvent as the developing fluid. This form of chromatography is known today as normal phase liquid chromatography(NPLC). The term reverse-phase liquid chromatography(RPLC) means a procedure that is a logical extension of NPLC. In this form of chromatography the mobile phase is more polarthan the stationary phase. It is unfortunate that many chromatographers tend to consider this a unique technique distinct from so-called NPLC since the technique is becoming very popular and is usedto separate a wide variety of mixtures.
THEORETICAL BASIS Chemists are more familiar withthe behavior of small moleculesthan that of macromolecules (oligomersand polymers), while chromatographers are accustomed to working with isocratic elution (constant composition of the mobile phase) rather than with gradient elution (variable composition of the mobile phase). It is not surprising then that there is some confusion when it comes to the principles of chromatographic separation of macromolecules. Practitioners often are puzzled by the outcome of some change in separation conditions. The apparent absence of predictability and of guidelines for method development also preventsthe full potential of these separations from being achieved. Such apparent anomalies in the separation of macromolecules have led workersto make new proposals for thebasis of such separations. Many chromatographers assume that macromolecules are retained at the column top, until at somepointthey are desorbedcompletely and then move through the column without further interaction with the stationary phase.
44
Chapter
Other workers have suggestedthat chromatographic migration in these systems occurs bya precipitation-redisolution process rather than by interaction of solute molecules with the stationaryphase; that is, solute solubility determines separation. Another view is that the multipoint attachment of macromolecules to the surface of the stationary phase leads to a retention process that differs fundamentally from that forsmall molecules. The general problem of chromatography is, in a practical sense, not solvable. For ordinary column chromatography unknowable variables exist involving everythingfrom the natureof the complex multisitesurface to the details of the method of packing the column. Assumptions can be, and have been made that allow for an approximate solution to the theoretical problem. The approximate results have been shownto confirm experience to a fairdegree. The principal problemof chromatography is separation of substances. In a typical procedure the material of interest is started from a band near the topof the column and is washed downthe column with pure solvent. As the washing proceeds,there is a separation of the original band into component substances. The value of the method is enhanced by any factor that can further the separation of the component bands, and that can minimize eachband dispersion. The mechanism of separation in LC is a subject of much debate [591. Snyder [8] describes and compares each of the proposed mechanisms. Presently there is no “best” model for all packings, solutes, and solvent strengths. Snyder’s model [5,8] provides a good understanding of alumina and is fairly good for silica with weak solvents. Other models [7,9] best handle silica with strong solvents and are useful for selecting solvents for gradient elution works. An important goal in separation science is to develop a quantitative understanding of the molecular mechanism of retention in LC. This would not only permit prediction of retention and separation behavior from molecular structures, but also permit the development of chromatographic methods for the purpose of exact physicochemical measurements of properties of solutions and forthe purpose of better understanding of interphases of chain molecules, including Langmuir-Blodgett films, micelles, and bilayer membranes. The statistical mechanical theories of polymer chain adsorption at a solution surface have been studied extensively by Rubinand Dimarzio [ 10121. These studies represent one of the first todevelop tentativelya theoretical basis of LC. The central problem of such a study is to enumerate all possible configurations of a flexible chain polymer in the vicinity of a solution surface and keep track of the number of monomer units in each chain configuration which lie (or are adsorbed) in the surface layer. With
Liquid Chromatography
45
this information, it is possible to assign a probability to each configuration which takes into account the energy gained with 7 monomer units are adsorbed in the surface layer and thus tocalculate the average properties of a polymer chain. Rubin [ 101 states that the polymer chain configurations are based on a lattice model in which there is a one-to-one correspondence between random walk paths on the lattice and polymer chain configurations. An isolated polymer chainat a solution surface is investigated. Onedimensional characteristics of the monomer unit distribution are determined analytically in the limitof a longpolymer chain, neglecting the self-excluded volume.The mean number of monomerunits adsorbed in the surface layer, is determined, assuming that one end of the polymer chain lies in the surface layer. The parameter N is the number of monomer units in the chain, and 8 is the adsorption energy of each monomer unit in the surface layer measured in unitsof kT. In addition, themean distance of the free end of the chain from the surface z(8,N) is determined. The lattice model considered include the simple-cubic, hexangonal-closepacked, facecentered-cubic, and body-centered-cubic lattices.For N + both and z(8,N) exhibit a very interesting discontinuity at a lattice-dependent adsorbtion energy 8,. For example, for 8 > e,, (which is also proportional to the average adsorption energy of a polymer chain) is proportional to N. For 8 8,, is proportionaltoa constant of order unity; and for 8 = e,, is proportional to NI'*. It is shown that the probability distribution of the end ofthe chain decreases exponentially with increasing distancefrom the surface layer for 8 > 8,. In addition, themean number of monomer units in the kth layer from the surface is determined for N 1 and 8 > 8, and is found to decrease exponentially with increasing k. In effect, for 8 > 8, the polymer chain exists inan adsorbed state. The adsorption of a long flexible-chain moleculeon a long rigid-rod molecule wasalso studied by Rubin [ 11 The principal difference between the rod-and surface-adsorption model is in the form of the function
for 8 > ln(6/5), where f ( 8 ) is the limiting average function of monomer units in adsorbing sites. In particular, as 8 decreases toward e,, the slope of thef(8) vs. 8 curve approaches 25 in the surface adsorption model whereas the slope and all higher derivatives ofthe f ( 8 ) vs. 8 curve approach zero in the rod-adsorption model. The rodlike molecule is represented by the lattice sites on the of a single-cubic lattice; sites which are nearest neighbors to the are adsorbing sites. The dimensionless adsorbtion energy per monomer unit is 8 = d k T . The problem of enumerating polymer chain configurations tak-
46
Chapter 3
ing into account the increased probability of occupying adsorbing sites and the zero probability of occupyingZ sites is formulatedand solved as a random-walk problem. This model aisnatural generalization ofa randomwalk model ofadsorption on a plane solution surface.The average function of monomer unitsin adsorbing sitesfR(0) is computed as the limit in which the number of monomer unitsin the polymer chain approaches infinity. On the other hand, DiMarzio and Rubin [ 121 apply the lattice model a of adsorbtion of an isolated chain polymer between two plates using matrix formalism and a grand canonical ensemble formalism. The matrix formalism is particularly convenieni for calculating the polymer segment density as a function of the distance from one of the plates for different fixed plate separations. The grand canonical ensemble formalism consists of loops (sequences of polymer segments whose ends are in contact with one plate and whose intermediate segments lie between the two plates), bridges (sequences of polymer segments whose ends are in contact with different plates and whose intermediate segments lie betweentwo plates), and trains (sequences of polymer segments which are wholly incontact with one plateor the other). All of the foregoing quantities have been calculated in the limit of infinite molecular weight as a function of the distance of separation between the plates and the energy of adsorption of a polymer segment on a plate. The self-excluded volume of the polymer chain is ignored. In addition, the average size loops, bridges, and trains, and the effective force of attraction between the plates is calculated. The above statistical-mechanical theory was later developed by Grosberg [l31 and Entelis [l41 and applied in the case of functionalized oligomers. Successful fractionation of high molecular weight homopolymers using gradient elution high-performance liquid chromatography (HPLC) has been reported [ 15-24]. For example, polystyrene homopolymers or oligomers in a molecular weight range 102-107 have been separated efficiently and rapidly by means of gradient elution HPLC utilizing either C-l8 orC-8 chemically bonded phaseand a methylene chloride-methanol mixed mobile phase [19]. Other mixed mobile phases such as THF-H20 has also been employed [20,24]. Separation of styrene oligomers also been achieved by supercritical fluid chromatography with a density-programmed supercritical n-pentane mobile phase Based on the above mentioned experimentaldata, a statistical thermodynamic theory of polymer fractionation and its application to gradient elution HPLC has been developed by Boehm, Martire, Armstrong, and Bui (BMAB-1) to describe the retention behavior of an isolated flexible homopolymer molecule distributed between a binary mixed mobile phase and an idealized stationary phase consisting of sorbed solvent on a homoge-
Liquid Chromatography
47
neous planar surface [27]. In this analysis the Flory-Huggins lattice model approach is applied to an isolated polymer moleculeand entrained solvent molecules in each chromatographic phaseand nearest neighbor interactions are included in the Bragg-Williams random-mixing approximation [28,29]. The BMAB-I theory successfully accounts for the observed experimental trends of an increasingly abrupt transition from very high to very slow retention asthe degree of polymerization,DP, of the polymer increasesand as themobile phase becomes sufficiently enriched to a critical composition of the better solvent for the polymer. The critical composition represents that mobile phase composition where the capacity factor becomes unity. The critical composition is predicted to be a monotonically increasing function of DP for flexible homopolymers of sufficiently largeDP (> 15) and this dependence emanates primarily from the molecular flexibility of the polymeric solute which allows sizeand shape alterations by solventuptake or exclusion in responseto its solvent and/or surface environment [28,29]. The dependence ofthe critical compositionon DPalso generatethe opportunity for polymer fractionation by gradientHPLC. The BMAB-l theory was subsequently extended to include intermolecular polymer segment interactions and thus be applicable to semidilute polymer solutions. This extension is hereafter referred to as the BMAB-2 theory [30]. The onset of the semidilute regime where different flexible polymer molecules begin to interpenetrate appreciably occurs in good solvents for a volume fraction of chain monomers given byd, = DP -'" [31]. Hence departures from infinite dilution can be anticipatedfor small values of d,, when DP islarge(e.g.,when IO3 DP 4 2 d, 2 1 X lo-').Whensolutesampleconcentrationduringelutionfallsin the semidilute solution range, concentrationeffects on chromatographic retention behavior must be included for meaningful comparisons between theory and experiment. The BMAB-2 theory predicts that the transition region between high and low polymeric solute retention becomes more gradual as the concentration increases. Later, Boehm and Martire[32],byapplicationof the McMillanMayer procedure, developa more general derivation ofthe BMAB theory. This is achieved by the derivation of a more general expression for the capacity factor k' for a flexible chainlike polymer molecule distributed between mobile and stationary chromatographic phases. This generalization of the original BMAB-l theory is more reliable for lower molecular weight oligomers since more general expressions for the solvent entrained polymer coil expansionfactors are introduced that apply for smaller values of DP. Theoretical predictions of partition coefficients of oligomers and polymers between imiscible solvent phases as well as explicit expressions are obtained for the chromatographic capacity factors and corresponding
Chapter
48
retention timesin gradient elution for flexible, chainlike oligomers and polymers. Furthermore, the authors also investigate the effects of including nonlinear (i.e., quadratic) contributions to the mobile phase composition dependence on In k’ on chromatographic retention timesin a linear gradient elution. The nonlinear contribution are found to be more important forlower DP solutes. In the infinite dilution limit, the BMAB theory applies statistical thermodynamics to investigate the equilibrium distribution of an isolated, flexible chainlike macromolecule between a binary solvent mobilephase and an idealized planar stationary phase surface with sorbed solvent(s). The relative phase preference ofthe macromolecule dependson DP, 6, all possible types of nearest neighbor interactions such as solvent molecule-polymer segment,solventmolecule-solventmolecule,polymersegment-polymer segment, solvent molecule and/or polymer segment-stationary phase surface site, and also the configurational entropy of the flexible polymer molecule in each chromatographic phase. The flexible polymer coil plus the entrained solvent molecules is assumed to behave as a swollen spherical (thin cylindrical)gel in a favorable mobile (stationary) phase environment. In its simplest linearform, theBMAB theory predicts that In k’ = S(4c - 4 ) = IAIIDP(4c
- 4)
or
where
and represents the slope of -In k with mobile phase composition in the case of nonzero solute concentration, c, and c = 0, respectively; k’ ,capacity factor (theoretical) for a flexible oligomer or homopolymer when the “exact” and asymptotic, large DP solute expansion factors areutilized; &, asymptotic limiting value of the critical composition as DP + m;4, phase ratio. A I asymptotically approaches a constant value independent of DP for large values which is usually negative for reasonable solutions of the mixed solvent mobile phase. In the simplest version of the BMAB theory which applies when only sorbtion of the better polymer solvent onto the stationary phase occurs, the following predictions for 4cand A I result:
4c = 4: and
-
lalDP-In
+ ~ I D P - ~+” c,DP” + c,DP“ln
DP
(5)
Liquid Chromatography
A1 =
x12
+
x13
- x23
49
+ dDP-4’5 + cDP
(6)
Here, 4:(0 &, 4c 1) is the asymptotic limiting value of the critical composition as M + and xu (ij= 1-3) represents the reduced interchange energy required to form an i-jnearest neighbor pair. The indices 1 and 2 respectively refer to the better and poorer mobile phase solventsand 3 corresponds to amonomeric segment ofthe polymer. The quantities a, b, cl, c,, d, and c introduced in eqs. 5 and 6 are independent of DP and depend on the interchange energies and weakly upon the mobile phase composition [321.
Eqs. 2 and 3 indicate that for large DP homopolymers, k’ = exp [ [ A lI M(& - 4)] undergoes an abrupt transition from a very large to a very small value within a very narrow mobile phase composition range centered at = &. Thus, a very slight changein mobile phase composition from &(l - e) to &(l + e), where e is a small positive infinitesimal such that lim e + 0 as DP + leads to an increasingly abrupt change from very large to very small retention of solute as DP increases. Eq. 5 predicts that & becomes a monotonically increasingfunction of DP for sufficiently large DP which asymptotically approaches r#~ as DP + Consistent with the above considerations, the BMAB theory also predicts that fractionationof homopolymersand oligomers with respect to DP is possible providedcertain requirements are satisfied:
:
The macromolecules are flexibles. A combination of a good solvent (1) and a poor solvent (2) for the polymer is employed in the mixed mobile phase such that xlz x13 - x23 0. The good solventis preferentially sorbed onto the stationary phase.
+
Furthermore, fractionation of higher DP homopolymers requiresgradient elution which commencesat aninitial mobile phasecomposition that is less than the critical composition of the lowest molecular weight homopolymer in the sample and themobile phasecomposition is then temporally enriched withthe better solvent to a final value, 4, that atleast exceeds the criticial composition of the highest DP homopolymer present. This can be achievedif 1 1 4, > For veryhighvaluesof DP, 4c increasesonly slightly withDP rendering fractionation more difficult. In a linear gradient, the temporal variation of the mobile phase composition is
4(?)= 4 ( 0 ,
+ Bt
t 0 (7) where q+?) and is the mobile phase composition entering the column inlet at time t and t = 0, respectively, and B is the rateof increase of thevolume fraction of the good solvent.The solute retention time, tR,in linear gradient elution if eqs. 2 and 3 apply for k is
Chapter
50
t~ =
to
+
(IAIIDPB)”ln[l
- 4CO))ll
+
[All DPBtoexp[IAII DP (4, (8)
where torepresents the column dead time.When
l 4 DPBto
expt 1
4 (+c - +(O))I
1
eq. 8 reduces to tR
= to
+ (4, - + ( o ) ) / ~ + ( S B ) “ln(SBt,,)
(9)
where S = IDP. This result can be utilized to determine the critical composition, 4,, and S = -a In k/a 4, by gradient elution measurements provided the linear approximation to In k given by eq. 2 is valid over the entire mobile phase composition range where chromatographically significant values of k are encountered (10 2 k 2 0.1). A linear relationship between In k and over the relevant composition range is anticipated to become moreaccurate as DP increases. In practice, B(tR - to) ismeasured for variousselectionsof the gradient rate, B, with +(o) and t maintained at fixedvalues.Linear regressionisemployed to obtain the best linear fit of B(tR - to) to ln(Bt,) and the gradient determined value of the slope, S,, and critical composition C$<,),are then determined from the resulting slope and intercept. In general, especially for the lower DP solutes, S(,) and +<,) will not agree with their isocratically determined counterparts since the actual In k‘ - isotherms are not linear over the entire composition range of chromatographic relevancethat is probed bythe gradient. The BMAB theory predictsin general that
+
+
+
+
Ink’ = IAIIDP(+, - 4)
+
c AjDP(+, -
+)j
j=2
where Aj 2 2 are monotonically decreasing functions of DP which vanish as DP + The nonlinearcorrections to In k’ appearing in the sum CF2AjDP(+, - + ) j contribute whenever the difference 14, - +I becomes appreciableand DP is sufficiently small that k is chromatographically measurable overan extended composition range. An important aspect of chromatography is the prediction of peak positions which means predictingthe capacity factor a given compound with changes in the operating conditions. For HPLC the capacity factor and selectivity are changed substantially when the mobile phase composition is changed. To solve this problem is necessary to derive an equation that describes the variation of the capacity factor of a given compound when the mobile phase composition is changed over a wide range of concentration, and then to find a means of predicting the values of the parameters in this equation from the molecular structure of the solute.
51
Liquid Chromatography
The capacity factor is determined by the partition coefficient, which is a macroproperty of a system. A fundamental retention equation (eq. 11) in HPLC has been derivedby Lu et al. [33,34] using a statistical thermodynamic model. In k’ = a
+ bCB +
C
In CB
(11)
The validity of this equation withchangingmobile phase composition over a broad range has been demonstrated in both normal- and reversedphase LC. The parameters a, b, and c have their own definite physicochemical meanings. Parameter a is related to the adsorption energy of the solute, molecular interactions between the solute and solvents, surface area of the adsorbents, phase ratio, molecular weight of the solute, the configuration factor of the mobile phase and temperature. Parameter b is only involved in the solution interactions existing in the giving mobile phase.Parameter c is an entropy function of an adsorbed solute. A simplified method can be used to calculate the value of a, b, and c in eq. 11 after four experimental steps, three retention value in the low-concentration range of a stronger solvent and another one with pure or a high concentration of the stronger solvent. Parameters a and c can be calculated from the firstthree retention data as a limiting conditions according to thefollowing equation: In k‘ = a
+ C In CB
(12)
and b can be calculated from the fourth datum according to eq. 13 (with pure stronger solvent) or 14 (in the higher concentration range of stronger solvent).
b=
Ink’
-a
CB
In k’ - a - C In CB b= (14) CB The value of CBin most reversed-phase (RP)-HPLC separations is higher than 0.1 volume fraction of the strong solvent, but inmost normalphase(NP)-HPLC separations CB isless than 0.1 or even 0.001 volume fraction of the strong solvent. The absolute value of in CBin RP-HPLC is much smallerthan that in NP-HPLC in most separations, the contribution of the term b In CBin eq. 12 to the retention value inRP-HPLC can be neglected in the case of small concentrations the strong solvent. However, in NP-HPLC solute-adsorbent interaction occurs, which is mainly due to interactions between polar groups of the solute and silanol groups and the absolute value of In CBis large, the contribution of In CBto the retention value inNP-HPLC is significant.
52
Chapter
In addition Ying et al. have independently developed a similar statistical thermodynamic theoryto account for retention and selectivity of solutes in RP-HPLC. It emerges from this theory that two driving forces dominates the retention process: the difference in the chemistry of the contacts of the solute with its surrounding molecular neighbors inthe stationary and mobile phase solvents and the partial ordering of the grafted chains which leads to an entropic expulsion of solute from the stationary phase. More recently Dill has proposed a partitioning model of retention based upon mean-field statistical thermodynamic theory, that describes a three-step molecular process by which the solute transfers from mobile phase to the stationary phase This three-step process involves creation of a solute-sized cavity inthe stationary phase, transfer of the solute from the mobile phase to the stationary phase, and closing of the solutesized cavity in the mobile phase. In the partitioning model, the solute is approximated to be fully embedded in the stationary-phase chains rather than adsorbed on the surface. Since configurational constraints are imposed upon the alkyl chains through their attachment to the silica surface, Dill describes the stationary phase as an interphase, which differs from a bulk system in that the surface to volume ratio of aninterphase is highand its properties vary with depth from the surface. The organization of the interphase is influenced by geometrical constraints of the interface, including the length and bonding density ofthe alkyl chainsattached to the silica surface, as well as the solvent which contacts the chains. In addition, the chains will adopt as much disorder as possible with the geometrical and solvent constraintsin keeping withthe second law of thermodynamics [ Partitioning here implies that the solute “embeds” in the constrained stationary phase chains and differs from bulk-phase partitioning only in the nature of the second liquid, herethe constrained alkyl chains. Dill’s partitioning model predicts that the retention process will be primarily driven by two forces. One is the difference in the c6ntact free energy of the solute in the mobile phase and the stationary phase. This prediction is similarto thatgiven by Yinget al. Althoughmuchvaluable information hasbeengained from these studies of reversed phase HPLC, there are severalissueswhichremain unresolved, and thedriving forcefor retention remains unclear. Glockner and coworkers haveformulated a precipitation model to describe the chromatographic retention behavior of polymeric solutes. This theory considers that the mechanism of separation process in liquid chromatography involves precipitation and redissolution of the polymer molecules. As has been shown, the traditional approach to RPHPLC is to start the elution with a polar solvent and to add a less polar
Liquid Chromatography
53
solvent (modifier) in the course of the run.This procedure yields a gradient in solvent polarity along the column. Its orientation is antiparallel for weakly polar solutes, i.e., the solvophobic interactions forcing the solute towards the apolar stationaryphase increase inthe direction of the migration. The role of solubility in RP separations was stressed by Locke as early as 1974 [44]. He suggested that the relative retention ofclosely related solutes depends on their solubility in the mobile phase. Later Horvath and Melander [45-481 discussed the separation process by the so-called solvophobic theory. The role of the stationaryphase is minimizedby solvophobic theory, and retention is thought to occur through an adsorption rather than apartitioning process. This theory describes a two-step mechanism for retention which involves creation of a solute-sized cavity in the mobile phase and-transfer of the solute to or from this cavity. The driving force for retention as described by solvophobic theory is the free energy change associated withthe two-step solute-transfer mechanism [45]. However, the solvophobic theory is a development of earlyattempts to explain the retention mechanism in HPLC that mostly neglected the influence of unreacted silanols of the silica based packings [49,50]. The mechanism proposed by Horvath et al. [45] began with the observation that neat aqueous eluents, which do not contain organic solvents, could also be used for the separation of small, relatively polar biological molecules on octadecylsilica. In the absence of an organic component from the eluent, however, the interaction between the solute and the hydrocarbonaceous moiety ofthe stationaryphase hasto be the sole causeof solute retention. In other words, the chromatographic process is governed by the hydrophobic effect [51]. This phenomenon responsiblefor solute retention can be pictured as a reversible association process between the hydrocarbonaceous ligand anchored to the surface and the solute molecule. Other noncovalent interactions such as ionic and hydrogen bonding, which have been widely exploited in aqueous liquid chromatography, are caused by a more or less strong liquid chromatography, are caused by a more or less strong attraction between the solute and the stationaryphase. In contrast, hydrophobic interactions originate from a net repulsion betweenthe water and the nonpolar ligand as well as the unpolar moiety of the solute. The tendency of water to reduce the nonpolar surface area ofthe molecules in contact with the solvent is then mainly responsible for their association. The driving force for the association with the hydrocarbonaceous ligand is the concomitant decrease in the nonpolar surface area exposed to the solvent. In thecase ofhydrophobic bonding it is mainlythe solvent that forces the molecules to associate rather than the attraction between them. The hydrophobic effect plays a very important role in life sciences and
Chapter
54
the subject has been extensively treated theoretically [52-541. The statistical approach that relates this phenomenon to hypothetical water structures, however, is less suitable to interpret the chromatographic process. On the other hand, a quite general theory has been developed by Sinanoglu [55]to describe the effectof the solvent on chemicalevents.Thissolvophobic theory requires essentiallyno adjustable constants and employs a relatively simple approach to treat the interaction between molecules having nonpolar moieties in polar solvents. In view of this exact theory, solvophobic effects are not restricted to neat aqueous media. However, the very high cohesive density of water is responsible for the hydrophobic effect, whichis the most pronounced solvophobic effect. In the model used by Horvath et al. [45] the interaction betweenthe solute and stationary phase in solvophobic chromatography is considered as a reversible association of the solute molecules, S, with the hydrocarbonaceous ligand, L , at the surface. Accordingly, solute retention is governed the by equilibrium (15)
S+L*SL
where the complex SL is assumedto be formed by solvophobic interactions and the process is characterized by the equilibrium constant, K, which is defined by
Molecular associations in solution can be conceptually broken down into two processes. One is the interaction of the molecules S and L to yield SL in a hypothetical gas phase without any intervention by the solvent. The other more involved process entailsthe interactions of the associating species and the complex individually withthe solvent proper. Using Sinanoglu’s expression [55] for the free energy change of the cavity formation and taking into account that
and In k’ = In K
+
(18)
Horvath [45] derived the following theoretical expression for the capacity factor, k: Ink’ =
- A Fvdw.assQc +-A FvdwS RT
RT
55
Liquid Chromatography
- 1 vZl3 + ln-RTV + ./NA,( R TV:’3 P O
where = overall standard unitary free energy change = logarithm of the phase ratio = free energy change ofthe process during the association in the gas phase = free energy changefor thesolute molecules = Avogadro’s number = proportionality factor 1 -
(- 1-)
4TE, 1
9
AA
Y AS
V ke PO E
- 2(E
-
+
2E 1 = polarizability of species j = static dipole moment of solvent = molecular volumeof the solute and of species j respectively = contact surface area of the associated species = surface tension = molecular surface area of the solute = mole volumeof the solvent = corresponding function for the entropy production associated with cavityformation [56] = a parameter that accounts for the entropychange arising from the change in“free volume” = static dielectric constant
Nevertheless, under certain conditions some of the terms of eq. 19 remain fairly constant so that furthersimplificationis possible. The exploitation of the solvophobic effect in chromatographic separations is, of course, not restricted to the use of nonpolar stationary phases. It can be extended to interpret other chromatographic procedures where solvophobic interactions play a predominant role. The solvophobic theory emphasized the very important role of the mobilephase and although it appeared valid for numerous chromato-
56
Chapter
graphic systems, particularly withwater-rich eluents, irregularities have been noted by many workers [57,58]. The solvophobic theory derives from the interpretation of Sinanoglu [59,60] that treatsthe effects of solvation on bimolecular binding processes. Bimolecular binding, however, is not an appropriatemodel for chromatographic retention process. Bimolecular binding simply involvedthe conversion of two smaller cavities into one larger one, in a given solvent. Chromatographic retention involves the transferof solute from one solvent, the mobile phase, to another, the stationary phase. This transfer process can involve either partitioning or adsorption, thesolvent beinga surface in the later case. The principal solvation process in chromatographic separation is the creation of an acceptor cavity in (or on) the stationary phase and the destruction of the donor cavity inthe mobile phase. Thus binding processes and chromatographic retention processes are quite different: the former require only the change of cavity sizein a single solvent, the latter requires creation of a cavity in one solvent and the destruction of a cavity in another solvent. The solvophobic theory is based on the premise that the only cavity which is relevantto retention is that in the mobile phase solvent; it neglects the acceptor cavity inthe stationaryphase. Consequently it predicts that retention should depend only on the surface tension of the mobile phase solventand not on the surface tension or other physical properties of the grafted stationary phase. In a partitioning theory such as the mechanism proposed by Dill [36] cavitiesare described through the binary interactions constants; their differences account for the driving force for retention. The solvophobic theory therefore errs in important respects. For example: it does not rationalize the general observation [61] that (1)In k’ should be a simple function of a relevant partition coefficient and (2)it specifiesthat retention should beindependent of the nature of the grafted chain phase. There is much evidencethat retention does depend on the grafted chain phase, someof which unambiguously cannot be interpreted interms of effects of the phase ratio [62]. On the other hand, some predictions of the solvophobic theory will resemble those of Dill’s theory [36] in some circumstances. Inasmuch as retention is increased byunfavorable solute/eluent interaction or by favorable solute/grafted phase interaction, then when the former contribution is dominant, predictions of the solvophobic theory will be qualitatively similar to the Dill’s treatment. Moreover, both the free energy of transfer and the free energy of creation of a cavity in the mobile phase dependapproximately linearly on the surface area of the solute. Thus the solvophobic theory should also resemble any partitioning theory in predicting the widely observed linear dependence of In k’ on thesurface area of the sorbent [63]. The idea of the availability of residualsurface silanols for interaction
Liquid Chromatography
57
with solute molecules gained more and more attention [64-661 until, finally, a rigorous mathematical model of a dual natureretention mechanism was proposed [67,68]. Generally unreacted silanols are considered undesirable but, as Nahum and Horvath [67] have emphasized, no detailed study has far focused on their role in determining retention behavior [69-721. Two examples [68,73] of total blockage of surface silanols in the literature show that this leads to deteriorationof separation. The maximum surface concentration of alkylradicalsin bonded phases doesnot exceed 4-5 pmol/m2 while the concentration of OH groups is believed to be ca-8pmol/m2. Thus it is well-known that all alkyl bonded phases contain unreacted silanols and only some of the unreacted silanols are blamed for poorseparation. The Snyder model is conceptually the easiest to understand and we will use it to illustrate the principles of liquid chromatography. This model shows that the support-solute interaction is the most important parameter governing the separation by LC methods. In fact Snyder and coworkers [ 1,5,8] have interpreted the chromatographic retention of polymericsolutes in terms of linear solvent strength theory. On the other hand, Snyder [20241 considers that the application of existing “small molecule” chromatographic theory to the separation of macromolecules (high polymers and oligomers) can explain many of the anomalies reported far. That is, the gradient separation of macromoleculesdiffers from the isocratic separation of small moleculesin degree, not in kind. Snyder [ l ] considered first isocratic elution. The separation of a threecomponent mixtureby this procedure may be represented conventionally in Fig. 1. The fractional migration of solutes a, b, and c along the column as a function of time after sample injection isshown in Fig. la, and the resulting chromatogram is pictured schematicallyin Fig. lb. The finalseparation can be described by the well-known equations summarized in Table 1 .forretention (eq. 1, Table l ) , bandwidth (eq. 2, Table 1) and resolution (eq. 3, Table 1). A good theoretical understanding of column efficiency of plate number N as a function of experimental conditions now exists, and can be summarized bythe so-called Knox equation [74]: h =
+ B-Y +
(20)
Here the reduced plate height h is equal to H/d,, where H is the usual plate height value (column length L divided by plate number N ) and dp is the diameter of particles used to pack the columns; is the reduced mobile phase velocity, equal to udJD,,, (U is the mobile phase velocity and D,,, is the solute diffusion coefficient). In principle, eq. 15 allows the calculation of N as a function of such experimental variables as column length, column
58
Chapter 3
Time
_j
Figure 1 Typical separation of a three component mixture by isocratic elution: (a) Fractional migration,(b) schematic chromatogram.
diameter, mobile-phase flow rate, temperature, sample molecular weight, etc. For application to a broad range of experimental systems, particularly involving both large and small molecules, it is also necessary to recognize that B and C of eq. 15 dependon the solute capacityfactor k‘ and molecular weight. The corresponding separation by gradient elution of the same threecomponent sample is shown in Fig. 2. The migration of each compound along the column is pictured in Fig. 2a, where a different pattern is seen compared to the isocratic separation shown in Fig. la: all three compounds Table 1 Basic Equations for Isocratic and Gradient Elution Elution Parameter Retention time, S Bandwidth, m1 Resolution, A t ~ / 4 Or 0 At#4u8 Capacity factor
tR = tok’
+ to + k’)N-”’
+ k,
(1)
t8 = t0klog(2.3ko/k)
= V,(l R, = (1/4)(a - 1)N‘”
(2) (3)
u8 = Vm(1+ k)N””/’ R, = (1/4)(a - l)N’”k/(l
k‘ = ( t , - t,)/t,
(4)
k
( W
+ k)
= t8/Ar$Sto= t$’/Ar$SV,,,
(W (3a)
(44
59
Liquid Chromatography
I
Gradient
20
Figure 2 Fractional migration (X/L) of solute blends along the column (2a) and resulting chromatograms for gradient elution (2b).
are initially retainedat the column inletafter the gradient is begun. Eventually the k' value for compound a (dashed curve in Fig. 2c) becomes small enough to allow migration ofthe compound along the column; compound a moves increasinglyfaster along the column untilit appear in the chromatogram (Fig. 2b). The same pattern is repeatedat a later time inthe separation for compound b, followed eventually by similar migration ofc. Compared to isocratic elution (Fig.lb), gradient elution (Fig.2b) provides more nearly equal bandwidthsfor compounds a-c, and faster overall separation. Equations in gradient elution for retention, bandwidth, and resolution also are given in Table 1. These are expressed in terms of the same parameters as forisocratic elution exceptthat k' is replaced bythe average k' value during gradient elution, ;f. Bandwidth and resolution are of special interest; it can be seen that equations 2 and 2a (Table 1) and 3 and 3a (Table 1) are virtually the same, except that k' is replaced byk in gradient elution. That is, separation and peak heights or detection sensitivity are controlledby the same factors in both isocratic and gradientelution. Method developmenttherefore proceeds in similar fashionfor both HPLC procedures. Of special interest in gradient elutionare the so-called linear-solventstrength gradients (LSS). These can be defined as gradients that provide roughly equal values ofk for compounds eluting at different times during
Chapter
60
the separation [l]. LSS gradients thus yield constant bandwidths for the various compounds separated (eq. 2a, Table 1) and equal resolution for band pairs with similar values of the separation factor a (eq. 3a, Table 1). As in isocratic elution for k' , there is a roughly optimum value of k: 1 < k 10. Eq. 4a (Table 1) describes k as a function of gradient time t8, flow rate F, and column dead volume V,. This is in contrast with isocratic elution, where k' is independent of separation time, flow rate, and column dimensions (other conditions being constant). This difference can lead to confusion when gradient and isocratic separations are compared. Retention time t8, resolution R,, and bandwidth us in gradient elution can be predicted from data forcorresponding isocratic systems (eqs. la-4a, Table 1). Thus it is necessaryto know values ofthe isocratic parameters K,, to,N , and S. For many isocratic systems (e.g. reversed phase HPLC) retention is given by: log k' = log K,,- S+
(21
The parameter S is the slope of the plot log k' vs. the volume fraction organic solvent. Whenplots of log k' vs. are nonlinear, the tangent to the curve at k' = k serves as an adequate approximation to linear log k' - 6 plots for purposes of relating gradient and isocratic data. Macromolecular solutes can be regarded as a polymer of a repeating unit Macromolecular solute is in competition with the mobile phase for the active sites of the support. This competition can be regarded as an equilibrium process:
+
( mobile phase) =
( stationary phase)
(22)
Taking into account the abovementioned competition, the equilibrium equation could then be written: where M refers to a molecule of mobile phase or solvent, and (m)and ( S ) refer to molecules in the mobile phase or stationary phase, respectively. Whether displacementis the most important factorin every macromolecular system cannot be stated at the present time. Other phenomena (e.g., solute-solvent interactions) may also beimportant. It can be seenthat one molecule ofsolute displaces some numberr of solvent moleculesMupon sorption of the solute. The value of r in eq.23 will be related to the size of the macromolecule because a larger solute molecule will covera larger part of the stationary phase surface, and therefore displace a larger number of solvent molecules upon sorbtion of This means that plots of log k' vs. will be steeper for larger molecules or the S value for larger solute molecules will be larger (see eq. 21). For
+
Liquid Chromatography
61
very large solute molecules ( > lo5 daltons) values of S can be 30- to 100fold greater than for small molecules, meaning that retention is then extremely sensitive to change in 4. This behavior of large solute molecule may appear strange to chromatographers who are more familiar with the separation of smaller molecules (lower values of S). Because of the dependence k on S in gradient elution (eq. 4a, Table l), the gradient separation of macromolecular samples requires different experimental conditions to achieve optimum values ofk’ during the separation. Chromatographers who have comparedthe resolving power of different columns for both large and smallmoleculeshave often drawn two conclusions: first, that the plate numbers measured for large-solute molecules are generally much smaller than those measured for small molecules (same column)and, second, that “good” columnsfor small molecules separation (large M values) are often “poor” when applied to macromolecular samples and vice versa. This again has been interpreted as evidence of a nonchromatographicprocessin the separationofmacromoleculesby HPLC. On the other hand, chromatographic theory holds that eq. 15 applies to all samples for a given column. These contradictory observations will be analyzed inthe following paragraphs. The reduced velocity y of eq. 20 is proportional to VD,,,.The solute diffusioncoefficient D, isroughly proportional to (solutemolecular weight) “0.4 which meansthat will be proportional to (molecular other factors being equal [l]. Thus present separations of small molecules with 3-5 pm particles usually involve y values in the range < y < 15, whereas macromolecule separations typically involvey values greater than 50. This meansthat eq. 1 is approximately givenas
h =A
15)
(24)
for small molecules,and as
h = Cy
> 50)
for macromolecules, because onlythe above terms from eq. 15 are significant in the indicated range ofy values. The above appliesto typical values ofA , B, and C in eq. 20 (largestN value) at about y = and then increases with increasingy. Thus, macromolecule separations with their large values of y will necessarily involve larger values ofh (and smaller Nvalues) compared to small-molecule separations on the same column. Also,other conditions being equal(dp,column dimensions, etc.), a good column for small molecule separations means a column with a smallA value (eq. 24), i.e., a well-packed column. A good column for macromolecule separations means a column with a small C value (eq. 25), implying particles with favorable mass-transfer properties
Chapter 3
62
(e.g., large pores, fast diffusion in the stationary phsse, no retention sites that are much stronger than average, etc.). Thus the factors that make a “good” columnfor separating small molecules are indeed different fromthe factors that yield large N values in the separation of large molecules. It should be noted also that the value of C is a function of both the column and the sample. Thus, columnswith 10-20nm porescanhave“good” values of C for small solute molecules, yet much larger(“poor”) values of C for macromolecules,becauseofslowerdiffusionoflargemolecules within small pores. Finally, columns with small values of both A and C for solutes of all sizes will be “good” columns for all samples. For separation of macromolecular samples by gradient elution it is useful to express peak capacity (or average R, value) and peak height (or Vug) in terms of the primary variables: column length L and diameter d,, flow rate F, gradient time tg,and particle diameter d,. Table 2 summarizes the resulting relationships for both isocratic elution (small molecules) and gradient elution for macromolecules. The starting point in Table 2 is the relationship for reduced plate highh: eq. 1, Table 2for small moleculesand eq. la, Table 2 for large molecules. These equations plusthe definitions of N( = L/H), h( = H/dp), and ( = udp/Dm)lead to expressions for the plate number N for each case. The proportionality of N to certain separation variables isthen given by eqs. 2and 2a (Table 2).For gradient elution, it is convenient to express N i n terms of the mean capacityfactor k, proportional to t y / L d f ( t iis defined equal to tg/At$, the time for a 0-100% gradient). For the final derivation of resolutionor peak capacity from eqs. 3 or 3a (Table l), and peak heightor ( V u v )from eqs. 2 or 2a (Table l), the value N from eqs. 2 or 2a (Table is used. In the case of gradient elution, advantage istaken of the approximate, empirical relationships:
Table 2 Isocratic Separation of Small Molecules vs. Gradient Elution of Large Molecules; Dependenceof Experimental Conditions Macromolecules molecules Small
adientelutionisocratic Relationship
[l/(l
Plate height,h (1) Ay’’3 Plate number,N DA’3L&3F-‘’3e Resolution, R, or [ ( D A ’ “ 1 ’ 2 d ~ ’ 3 ~ ’ ‘ 6 ~ ) ] peak capacity, [k’/(l + k ’ ) ] PC Peak height or [DAI6L-”2@‘3F-1’6~w’] (4) (l / d k’)]
+
CV (la) D,t:(kCdi) - I (W D1/2(~’”(k)-(0.5+d/2 m 6’ p
Dgfrl2(fi)-I/zF-1 (k)-(o.5+n)/26~
P
(4a)
Liquid Chromatography
k -a l + k
63
(ZI’’~
and (27) where -0.5 n 0.3. Eqs. 3a and 4a (Table 2) apply to the separation of macromolecules by gradient elution. The column parameter n is close to -0.5 for reversed phase systems (either small or large molecules), but should be larger if stationary phase diffusion is markedly retarded. For reversed phase systems, with n taken as -0.5, eqs. 3a and 4a (Table 2) then yield simplified equations for gradient elution of macromolecules. Peak capacity or average R, is proportional to
and peak height isproportional to
Eqs. 28 and 29 can be contrasted with corresponding relationships (eqs. 3 and 4, Table 2) for resolution and peak heights in isocratic elution. Unlike isocratic elution, gradient elution separations are somewhat insensitive to the column dimensions chosen.Peak capacities (or average resolution)and average peak heightsare similar for thetwo separations. Average resolution and peak capacity are predicted (eq. 28) to be independent of phase rate, and this is proved by experimental data [61]. These data also show that peak capacity increases regularly with gradient time tg, as predicted by eq. 28. In Ref. 69 the effects of flow rate and gradient time on peak height values are shown for the same system. The decrease in peak height predicted by eq. 29 vs. increase in t8 or F is again confirmed. This same study also showedthat a 5 pm particle column gave pm volumn, again in roughly double the peak capacity found for a agreement with eq. 28. Other examplesfor the applicability of eqs. 28 and 29 for thereversed phase separationof peptides and proteins using gradient elution are presented [70], and quantitative agreement has been observed between experimentaldata andmodel basedon small-molecule HPLC. The Snyder’s model also provides insight about the question of how macromoleculesmove through a columnduringgradientelution:unretained vs. retained. Figure 3 illustrates how band migration in reversed phase HPLC changes with change in the sample molecular weight, other conditions held constant. In Fig.3a the elution of a dalton (small molecule) solute is shown under conditions (eq. 2a, Table 1) that yield a
Chapter
64
a
b
C
Figure 3 Typical migration in the gradient elution separation of compounds of varying molecular weight: (a) 100 dalton solute, conditions chosento give k‘ 3; (b) 10,OOO dalton solute, other conditions the same; (c) l-million dalton solute, other conditionsthesame; X/L isfractionalmigrationdistance.(AdaptedfromRef. 196.)
value of k’ equal to 3. This separation can be compared with that of Fig. 3c. It is seen that the k’ value of the band varies from about 10 to 1.5 during most ofthe migration process. In Fig. 3b the similar separation ofa 10,000 dalton solute is shown. Because of the larger value ofS (see eq. 21) for this compound, the valueof k isreduced to 0.5 (eq. 4a, Table l), and k’ varies from about 2 to 0.2during migration. However, significant retention of the band exists over the entire course of its elution from the column. In Fig. 3c, for the gradient elution of a 1 million dalton sample, the value of k is only 0.07, and the sample is essentially unretained during its elution (0.05 < k’ < The separation conditions of Fig. 3c are
Liquid Chromatography
65
suboptimal for the separation ofsuchmacromolecularsamples, and a change in column dimensions or flow rate as to increase F ) would be expected to improve separation markedly-without any change in tg. It is unlikely that many gradient separations of macromolecular samples are carried out asin Fig. 3c-without significant retention ofthe sample during elution. Table 2 illustrates another characteristic feature of the gradient separation of macromolecules. Here it is seen that as solute molecular weight becomes large,the band is elutedin almost the same mobile phase composition 4 for the two different columns: for the 50,000 dalton solute 4 = 0.873 for the 6 nm pore columns vs. 4 = 0.870 for the 30 nm pore column (corresponding 4 values for the 2000 dalton solute are 0.804 and 0.750). That is, it appears that the column plays no role in determining separation for largemolecules. It is also found that elutionoflargemolecules at constant 4 occurs when other conditions (column length or diameter, flow rate, and gradient time) are changed-unlike the case for small molecules. Actually, the present model predicts just what has been observed: elution of large moleculesat approximately constant4. Thus eqs. la and 4a (Table 1) can be combined with the dependence of K,, on column surface area to yield (for 0-100% gradient) [71]:
4 (at elution) =
tg - to - log 2.3K,,
-
ti
S
log \k +-+S
log E,, S
Here k,, = K,,",where \k is the stationary phase volumefor a given column with k,, = K,, by definition [71]. For a given solute, its value of S will become large as its molecular weight increases, thereby making terms ( 2 ) and (3) from eq. 30 small. Therefore in the limit, for very large sample molecules terms (2) and ( 3 ) from eq. 30 can become negligible, that at elution becomes constant for columns of different surface area and for different experimental conditions. Note that differences in the solute also affect term(1) of eq.30. Because K,, increases with solute molecular weight, however, term (1) of eq. 30 does not become small for large-solute molecules, as doterms (2) and of the same eq.30. However, the Snyder's model is incapable of predicting that the mobile phase compositionat the transition dependson and increases monotonically with the degree of polymerization ofthe solute. Hence, the Snyder's model cannot theoretically forecast (although it might experimentally anticipate) homopolymer fractionation by molecular weight through gradient elution HPLC. On the other hand, the model proposed by Snyder fails to provide a theoretical prescription for the determination of phase composi-
Chapter3
66
tion at the transition and its dependence on the solute’s degree of polymerization, thechromatographic environment, and the structural andchemical nature of the macromolecular solute. The polymeric attribute of flexibility plays an important role in determining the dependence of mobile phase composition and the retention time of degree of polymerization. The absence of such flexibility in small and/or structurally rigid solute molecules leads to a decidedly different dependence of retention time on degree of polymerization for flexible polymer behavior. These examples challenge the Snyder’s model contention that retention of macromolecules can be understood in terms of small moleculesretention. Based on the Snyder theory of retention, Jandera et al. [72-791 proposed the following approximate equation to describe the dependence ofk‘ of the oligomeric solute on the molar fraction or volume concentration of the organic solvent mobile phasefor reversed phase HPLC: log k’ = a - m4
(31)
and for more polar organic solvent in the binary organic mobile phase in the case ofnormal phase HPLC: log k‘ = a
- m log 4
(32)
The constants a and m in eq. 31 depend on the organic solvent and the stationary phaseused and on the sample solute polarity, which can be expressed in terms of the interaction index, I,, and size, given as the molar volume, V,. In oligomeric series, both I, and V, change linearly with the number of structural repeat units, n, in a given series, that leads to the following expression for thesimultaneous dependence of k’ on n and 4: log k’
+ log 0 + n log a = a, - m,+ +
- m14)n
(33)
Here log a characterizes the separation selectivity between the neighboring members ofa given seriesand log 0 can be looked upon as a measure ofthe overall retention in a givenseries. The partial constants a,, a,, m,, m, depend on the molar volumes (AV,, V,,) and on the polarities ( A I,, I,,) of both the repeat structural unit (AV,, AI,) and the structural residue (V,,, I,,) in a given series [76]: a, = K ,
+ KZVOX
- K3 VOJOX
m, = K ;
-K; a, = K4AVx - K s ( I o A V ,
m, = KGAV,
- K;(I,AV,
+ AIxVox)= K4AVx - KsQ’ + AIxVox)= KiAV, - K ; Q ’
(34) (35) (36) (37)
Liquid Chromatography
67
Here, K, to K5 are constants independent of the organic solvent in the mobile phase and K ;to K; are constants that depend on the nature of the organic solvent. The most important factorscontrolling the selectivity inan oligomeric series in reversed phase HPLC systems are the increments of the molar volume, AV,, and theconcentration of the organic solvent, Cp,in the mobile phase. However, the combined structural term Q' = (&AV, AIxVOx) may also have a significant effect on selectivity in the oligomeric series,in contrast to thebehavior of small molecules The constants a and m in eq. depend on the specific surface of the support, on its activity (a'),on the solvent strength (polarity, e') of the mobile phase and on the properties of the solute, its energy of adsorbtion from n-pentane (Q") and the area occupied by an adsorbed sample molecule on the surface of the support (As). These properties are assumed to increase linearly with the number of repeat structural units (n) in a given oligomeric series, wherethe simultaneous dependence ofk' on n and Cp has the following form
+
log-k' = log /3
+ n log a = U, - m, log
+n(a, - m,log Cp)
#I
Here log a is the measure of separation selectivity and log p a measure of the overall retention in a given series as in eq. that applies in reversed phase systems. Thepartial constants a,, m,,a,, m,are related to theadsorption energy of the repeat unit (Qi) and of the structuralresidue (Q,)and to the areas adsorbed by an oligomeric unit (Ai) andby the end groups (A,):
m,,= A, nb
mi = Ai nb
K6is an auxiliary-adsorbent dependent constant, Eb is the solvent strength, and nbis the area occupied by an adsorbed molecule of the solvent b used as the more polar component of the mobile phase. In conclusion the most important factor controlling the separation selectivity in reversed phaseHPLC is the size and polarity of the oligomeric unit but the polarity and size of the end groups may also be important, as the order of elution may even be reversed in two oligomeric series withthe same repeat structural units, when the end groups differ largely in size and/ or polarity. For oligomeric series with bulky and polar end groups, the
Chapter 3
68
selectivity is not affected significantly by the concentration of the organic solvent in binary aqueous-organic mobile phase. Similarly, in normal phase HPLC, the selectivity is not significantly affected by the concentration of the polar solvent in binary organic mobile phases when used with an oligomeric series with small and not strongly polar oligomeric units. In this case, the selectivity can be controlled bythe choice of the nature of the polar solvent in the mobile phase or by the selection of the appropriate adsorbent. Selectivity may also be controlled by adjusting the ratio of two different polar solvents inthe ternary organic mobile phase. It has been confirmed experimentally[79] that the separation selectivity of the individual oligomers is controlled principally by the adsorption energy and adsorbed area of the structural repeat unit, by the nature of the support, and by both the polar solvent and its concentration in the mobile phase. Recently, Jino andChen [801 proposed a fundamental retention equation: n-l
In P = a
+ C biln cmi+
n-l
cicmi
(43)
i= I
where C is the volume fraction of the organic modifier, a, b, and c are constants related to the adsorption energy of the solute and organic modifier, phase ratio, and temperature, respectively. The displacement model is useful in discussing the retention mechanism of adsorption chromatography [8l This model defines and allows evaluation ofthe number of solvent molecules in the mobile phase( r value) required to displace a solute molecule adsorbed to the surface of a stationary ligand. The retention mechanism of reversed phase HPLC, where the chemically bondedstationary ligand may act as both partitioning phaseand adsorbent, has often been explained accordingto the liquid-liquid partition of solute between the bulk and adsorbed layers of the mobile phase. It is expected, however, that the displacement model applied to reversed phasg HPLC can evaluate the extent of the adsorbtion site, that is, the surface area of both solute and ligand involved in substantial retention on the bonded hydrophobic phase[ 82-84]. Based on the displacement model it is postulated that a solute molecule (S) isadsorbedtothenonpolarligand (L) incompetitionwiththe organic solvent molecule( D ) in the aqueous mobile phase.The adsorption and desorption equilibrium is expressed by DmS
+ DJ
= rD
+ Dm+,,+SL
(44)
where DmS is the solute molecule solvated with m molecules of organic solvent in the mobile phase, and DJ is the stationary alkyl ligand solvated
Liquid Chromatography
69
with n molecules of organic solvent. When the solute molecule (D$)is adsorbed to the ligand (DJ), r molecules of organic solventare released in total from both contact surfaces. Thus, the solute molecules adsorbed to the ligand are solvated with (m n - r ) molecules of organic solvent and desorbed from the ligand by solvation of r molecules of organic solvent. The equilibrium constant(K) is given by
+
and capacity factor k’ is given as
where V, is the volume of the stationary phase and V, is that of the mobile phase. From eqs. 44 and 45 the capacity factor k’ may be obtained from the following equation: log k’ = r log
+ log ( tDJlKV, )
(47)
Eq. 47 predicts that the r value is given asthe slope ofthe plot of logk’ vs. log obtained under conditions satisfying the displacement model where the second term inthe right-hand side of eq.47 is independent ofthe organic solvent concentrationin the mobile phase. However, the exact mechanism of liquid chromatographic separations are not presently well understood. From the myriad of proposals of the mechanics of the solute retention in liquid chromatographic methods, it is now apparent that no single retention mechanism is operative in HPLC; rather, solute selectivity is based upon mixed mode mechanisms including solvophobic and silanophilic interactions. On the other hand, one of the main problems in chromatography is to predict the retention of compounds by studying their physicochemical properties. This means to predict the properties of a substance when the structure is known. There is also another possibility, namely to predict the structure from the properties. To use system and solute properties for precalculationofretentionis the usual task ofquantitativestructureretention relationships in chromatography, whereas in spectroscopythe resulting spectraare used for structure elucidation. Generally, it is assumed that the chromatographic retentionon a given stationary phase is influenced both by extensive (molecular mass, number of atoms, etc.) and intensive (structural features) solute properties. Such a differentiation is similarto that in spectroscopy.The absorbtion band in IR
70
Chapter
spectroscopy, for example, of a ketone C=O group is at about 1720 cm-'. This value is due to the vibration of the bond between two atoms with corresponding mass (extensive property). This band moves down to 1670 cm - I or up to 1820 cm - I depending on the neighboring atoms and/or functional groups. Hence a band anywhere between 1670 to 1820 cm" could be connected with the presence of a C=O group. Its exact location serve for structuralelucidation. If a valid rule (equation) aboutthe dependence of chromatographic retention on some generalproperties of a series of compounds can be defined, any deviation from this rule can also be connected with a given influence of a corresponding functional group and, as a next step, the influence of neighboring atoms on the functional group in question. It is now impossible to predict retentions by precisely describing the chromatographic process and calculating intermolecular interactions in a chromatographic system. Methods using the correlation between different properties of analyte compounds and their retentions are now in widespread use. To calculate retention, use has been made of solubility parameters, retention indices [SS],solvent interaction indices [86,87],the correlation between retention and hydrophobicity constants [SS], distribution constants, molecular areas [89-931,Van der Waals volumes, dipole moments and the number of carbon atoms in the molecule [941,molecular connectivity [95-971,etc. Some of the approaches use the relationship between the activity coefficients ofa substance in a certain chromatographic system and retention [9S].A calculation method has been proposed that involves two contributions to selectivity, a polar and a nonpolar one [99,1OO].A series of alkyl-benzenes are used to standardize the retention scale, which can then be employed to calculate the retention and selectivity of the compounds investigated, for different mobile phase compositions. A method has been developed to predict the retention of compounds in reversed phase HPLC based on the molecular structure of the analyte [loll. The retentions are calculated as retention indices on thealkyl aryl ketone scale. The increments for substitution on aromatic and aliphatic carbons have beenobtained, and a program for calculating retention indices has been developed[ 102,1031. Empirical correlation approaches are normally not associated with specific retention theories, that their applications are limited. To use these approaches one must have experimental results from studying the physicochemical and chromatographic properties of compounds and reference data (often unavailable) on new or rare compounds. The retention theories on reversed phase HPLC do not provide adequate means of calculating the retention of compounds [lM-1141.The solvophobic theory [46,111,112]now seems to give the most suitable approach to calculating retention and selectivity; however,to determine the energy contributions to
Liquid Chromatography
71
retention it is necessary to know such characteristics as the area of the hydrophobic contact with the sorbent surface, the acentric factor, and dipole moments. Normally a full set of characteristics is not available and it is very difficult to derive them. The same is true of molecular statistical approaches [ 113,1141 that require a preliminary determination or acomplicated calculation of the activity coefficientsfor compounds in a chromatographic system. To develop a method for calculating retention and selectivityitis necessary to employ some model concepts ofthe retention mechanism, the surface layer structure and the character of interactions of retained substances with mobile and stationary phases. Much theoretical and experimental evidence has recently been produced to show that a bonded hydrocarbon layer seems to have a structure intermediate between brush and liquid and the eluent molecules are able to penetrate this layer producing a considerable effect on its properties [ 115,1161. The penetration increases with increasing solvent hydrophobicity [ 112,1151. It has been shown that thechromatographic process simultaneously involves both thedistribution and competitive adsorbtion in reversed phase HPLC. The distribution processes are dominant and the surface layer exhibits quasiliquid properties [ 112,1171. To calculate approximately the retention and selectivity, a twolayer and a linear model of a chromatographic system were recently proposed respectively byGalushko [ 118,1191 and by Dimov [ 1201. The two-layer model postulates that (1) the surface of a modified sorbent in HPLC has a surface layer (SL) consisting of octadecyl radicals and some of the components of a mobile phase; (2) the surface layer is assumed to be a quasiliquid that has its own characteristics, i.e., surface tension (S,) and dielectric constant (c,); and (3) the molecules of a retained substance penetrate into the surface layer. The retention is determined by the difference in molecule solvation energies in the mobile phase and surface layer. In fact the surface layer is regarded not as a true hydrocarbon layer but as a specific layercontaining surface-fixed alkyl radicalsand some account of mobile phase components. It is obvious that this layer should have characteristicsdifferent from those of a hydrocarbon. By assuming a surface layer that has certain average characteristics and thepossibility ofa substance penetrating this layer, a simple procedure is applied for calculating the retention. The general expressionfor the retention is
-AG
Ink’ = -+ RT
+
+
where is the phase ratio. The retention is determined bythe differences in the solvation energies inthe distribution system [ 1101:
Chapter
72
According to Refs. 110, 121, and 122, AGso~v AG = AG,.,
- AG,.,
+ AGinps - AGi,,,.,
(50) (51)
where AG,., and AG,., are the energies required to generate a cavity of molecular size in the surface layer and mobile phase, respectively; AGint., and AGint.mare the energies of the interaction of the molecules with the surrounding medium in the surface layer and mobile phase, respectively. The simplest version is[46] AG, = NAY
+ NAly(k: - 1 )
(52)
where N i s Avogadro's number, A is the cavity surfacearea in the liquid, y is the surfacetension (for watery = 72.6 nm"), A, is the solvent molecule area and k: is the characteristic constant for every liquid (for water ki = 1.277) [ 1221. To calculate the approximate value ofA, the Van the molecule regarded der Waals radiusof a molecule is normally used with as spherical [ 1221. In this instance an approximate value of the molecular area is derived whereas the value of the area of a cavity generated in the solvent appears to be more correct [121]. The simplest and the most exact way to determine the cavity area in a solvent is to use the experimental values of practical molar volumes of different compounds in this solvent. The modern methods of measurement make it possibleto obtain values of partial molar volumes with an error of less than 0.1 cm'mol " [ 1231. The literature reports numerous data on partial molarvolumesofdifferent classes of compounds such as alcohols, hydrocarbons, ethers, and amino acids. The value of partial molar volumes for several hundred substances have been collected [ 1231. Experimental data for many compounds have shown that the additivity ofthe action of separate molecular fragments isa good approximation for calculating molar volumes[ 1231. Thus considering the cavity shapeto be spherical,the following relation can be written:
where are the increments of partial molarvolumes of fragments. A large set of experimental values of partial molarvolumes for different compounds [ 1231 enable us to find the values of for almost any structure. In addition simple equations have been proposed to calculate the value of with great accuracy [123-1251. Thus the value of AG, can be calculated as follows:
Liquid Chromatography
AG, = N1”y4.836
73
[( F K )
2/3
+
(k‘, - 1 )
1
where v, is the molar volume ofthe mobile phase. Note that tosimplify the calculations, only the partial molar volumes obtained in water are used, assuming the cavity parameters in a surface layer and a mobile phaseto be similar[ 1231. An important point is a correct choice of the form of the potential of the interaction of the solute withthe surrounding medium, AGint.Solvophobic theory uses the sum of Van der Waals and electrostatic interactions [46,110,111,123]. AGi,
AGVdW
+ AG,.,
(55)
Here Onsanger’s continuum model of a reactive field and a complicated expression derived by Haligoglu and Sinanoglu [ 1221 are used by solvophobic theory [ 11 l ] to calculate the Van der Waals interaction energy. As mentioned above, to calculate thisterm, it is necessaryto know the characteristics ofa substance whichare unknown and difficult to obtain. It should be noted that almost all approaches for calculating the VanderWaals interaction energy are approximate and need a great number of sophisticated characteristics of substances [ 126,1271. At present the continuum theories involving only electrostatic interactionsare applied for an approximate calculation ofthe solvation energy. The model proposed by Galushko [ 118,1191 considers that the molecule of a substance may be considered as consisting of dipoles, each of which separately interacts withthe surrounding continuum. In this case
where pj are the bond dipole moments, ajthe effective radius of an imaginary sphere in which the dipole is locatedand E the dielectric permittivity of the surrounding continuum. Such a model does not need quantum chemical methods to calculate the atom charge. The bond dipole moments are determined for almost all bonds and, in many instances, vary insignificantlyfor various compounds [ 128,1291. More strictly, each dipole is not surrounded by a totally closed sphere of solvent molecules; it is more correct to speak about ball segments. The approach proposed by Galushko[ 1 18,1191 is basedon the assumption that in different compounds the parameters of a ball segment in whichthe same dipole is located, vary ainsmall range that to calculate the electrostatic energy the parameters can be approximated by the effective radius of the sphere (aj).By substituting eqs. 54 and 56 in eq. 51, the following equation can be written:
74
Chapter
-AG = N'"4.836
[
( F V,)
2/3
(ym
-
'
+ v","(
k', - l)ym
+
wheref(E) = ( E - 1)/(2~ 1). The expression obtained involves several unknownparameters of surface layer: k:, f ( ~ , )ys , and v,. To determine the parameters of the surface layer for a given sorbent and column, a standard substance is used, e.g., benzene, and calculate the values for surface layer relative to this standard. Then
[( 7V,)
2/3
RT
N1"4.836(yrn-
+ [ f ( e , ) - f ( e r n ) ] ( C !a; d-C j
j
l)&
-
(
+ Ink:,
(58)
Thus when a standardsubstance is used it is not necessary to determine the values of and k:, which simplifies further calculations. Eq. 58 can be reduced to a more usefulform
+ 16.48(yrn-
Ink: = Ink:,
[( F v.)
2/3
- (Vg)"]
where AGe.s.j.Hzo and AG,.,.~., are the increments ofthe contribution AG,.,. for dipolej of molecule and the contributionof (AG)e., for the standard substance in water, respectively. Here AG is expressed in kJ mol", in nm and V in cm mol -l. The values of and AE,)can easily be found by using, in addition to a standard, two or more reference substances.The simplest way is to solve eq. 59 graphically for those reference substances, assuming Ink: (calculated) = Ink:(experimental). Thus, eq. 59 can be expressed in the form
-
f(%) =
-b./,
+
(60)
where y,b
- f(c,)c
+ Ink:, - Ink: C
b = 16.48
( F V,)m -
Liquid Chromatography
c = 0.8234
75
2 AGe.s.j.~20- AG,.a.Hzo)
Taking into account two artibrary values of and using eq. 60, one can calculate two values of f ( a ) for each reference compound and construct plots of -ys vs. f ( ~ ,for ) these compounds.The coordinates of the intersection point determine the values of surface layer parameters [-ys and f(~,)]. Naturally, to determine the value of and&) more precisely, it is necessary to employ compounds that have a large difference in AG, and AG,.,., i.e., differing in size and polarity (e.g., benzene, benzophenone, o-cresol and phenol). Using the retention data for various organic compounds [ 130,131] and eqs. 58 and 59, the applicability of the above approach was tested. To determine the increments the value of partial molal volumes given for many compounds in [l231 were used. The basic fragments of compounds are given in Table 3 [ 1 181. Eq. 56 involves an empirical parameter, the effectiveradius. This
Table Fragment' -CHz-
Increments of Partial Molar Volumes for Some Fragments
v,
cm3.fnol" 6.8 16.0
Fragment "OH -CH20H
v,
cm3-mol" 11.7 28.2
Fragment -CO-NH2 -CH-COOH
v,
cm3.mol" 29.0 33.4
I -CH3 -CH,(ar) =CH-C,H,
26.4 22.5 13.5 74.5
"COOH -COOH(ar) \ 7C=O
-c-0-
25.9 23.5 13.0 20.0
-N(CH3)2 "c1 =S=O -NH-
-C,jHd-
65.3
-C=O
22.3
-CEN
20.5
21.6
"NH2
14.7
49.2 20-22 16.1
7.0
I
-0-CH,
5.2 31.5
H "NO2
'ar = aryl. bNo data concerning the partial molar volumesof Cl-containing compounds have been elucidated in the literature; the value is derived from increments of the volume in molecular crystals 11261. Source:Ref. 118.
Chapter
76
parameter may be derived either experimentally or using some physical considerations. Instead of a complicated quantum chemistry formula, a simple relationwas used for the determination of cyp
where rl and r2 are the Van der Waals radii of the atoms contained in the dipole and g is a correlation parameter. The initial condition isg = 1, i.e., the radius of a sphere is half the sum the Van der Waals atomic radii. Using this value and choosing benzeneas a standard substance (V, = 81.3 cm3-mol" and AGe.s.st.HzO = 26.16 kJ-mol"), Galushko [l181 resolve graphically eq. 60 for phenol, ethyl-benzene, o-cresol and benzophenone (Fig. 4). The Ci and Ci AGe.s.jH,ovalues for thesecompoundswere calculated by usingthe increments from Table and Table 4. Fig. 4 shows that the straight lines intersect in a very limited region, defining the limits Table 4 Increments of AGc.s.jH20 for Some Dipoles
CS&" C,3 -H C&"SP3 CsP2-Csp csp3 -cap
c-0 c=o
C-N C=N 0-H(ar.acid) 0-H N-H N-0 N=O c-Cl
c-S
1.49 1.49 1.80 1.80 1.80 1.66 1.74. 1.69 2.37 1.35 1.20 1.38 1.55 2.20 2.34 1.8
1.oo 1.oo 1.oo
1 1.oo 1.oo 1.05 1.oo 1.40 1.oo 0.89 1.oo 1.oo 1.42 1.30 1.oo
0.7 0.4 0.68 1.15 1.48 0.7 2.4 0.45 3.1 1.51 1.51 1.31 0.3 2.0 1.59 0.9
4.36 1.42 2.33 6.68 11.06 3.15 32.20 1.24 21.25 27.28 38.80 19.20 0.71 11.04 5.80 4.09
kyl. bFor calculation of = (r, + rz)/2, the Van der Waals radii (r) from Ref. 131 were used: C = 0.18; H = 0.117; 0 = 0.152; N = 0.15; Cl = 0.18 nm. 'For calculation of Ae.t.jH eq. 56 was used. Source: Ref. 1 18.
77
Liquid Chromatography
20
40
60
Figure 4 Determination of surface layer ligand parameters of Merck RP-18 sorbent.Compounds: 1 = phenol; 2 = o-cresol; 3 = benzophenone; 4 = ethylbenzene. (Adapted from Ref. 118.) (E, = 5.5 + and = - 43.10-3nm”. These values seem to be reasonable for the parameter of a surface layer. It should be mentioned that the surface layer of a modified sorbent was characterized in Ref. by a quantity such as dielectric permitivity, and the value of E, reported was A different value of of was derived in Ref. using another method of calculation and a different octadecyl sorbent. The calculated results given in Table show that the simplest approach todefine the value ofajas half the sum of Van der Waalsatomic radii generally results in good agreement between the calculated values of In k’ and those given in Ref. The results of calculating AG,.,and the parameters for calculating these valuesare given and show that thevalue of g for many dipoles is only slightly different from unity, except for the dipoles -C=N, -N=O and -C-Cl. The method proposed by Galushko does not allow usto take into account the decrease in the interaction of a molecule of a substance with water produced by an intermolecular hydrogen bond. The value of kJmol” (average hydrogenbond) seems to be a reasonable correction. The results given in Table 5 show good agreement betweenthe calculated and experimental values. It is necessary to explain the difference between In k:,, and In k& for naphthalene and anthracene. The values of In k’ in H 2 0 for these compounds were derived by linearly extrapolating the value of In k’ measured at high concetrations of methanol in the mobile phase [ It was shown later on that for naphthalene the dependence of In k’ on methanol concentration passes through a maximum at low metha-
~(EJ =
Chapter3
78
Table 5 Comparison of Calculated and Experimental Values of In k' [ l 181 Compound Aniline Dimethyl o-phthalate Phenol 2,4-Dimethylphenol Benzyl alcohol Quinoline Benzaldehyde Anisole o-Nitroaniline N,N-Dimethylaniline m-Nitrophenol Toluene 2-Phenylethanol Chlorobenzene m-Dinitrobenzene Diethyl o-phthalate Benzonitrile Benzophenone 1Phenylethanol Ethylbenzene n-Nitroacetophenone Anethole o-Cresol Diphenyl ether Acetophenone Biphenyl Nitrobenzene Naphthalene 3-Phenylpropanol Anthracene N-Methylaniline Benzene
In kf, 2.63 4.84 3.10 5.13 3.26 5.13 3.80 6.20 2.34 7.38 2.74 5.86 4.22 6.08 4.14 6.40 4.00 6.57 3.91 7.12 4.01 8.60 4.30 8.18 4.47 8.34 4.45 7.17 4.85 9.22 5.08 4.95
In k: 2.94 5.09 3.13 5.22 3.26 5.58 3.72 5.77 3.81 6.26 3.89 6.27 3.89 6.44 3.99 6.46 4.00 6.96 4.04 7.38 4.18 8.13 4.23 8.58 4.34 8.91 4.42 11.81 4.94 12.84 5.01 4.95
Difference 0.31 -0.25 0.03 0.09
-
-0.45 -0.08 0.43 - 1.47 1.12 -1.15 -0.41 0.33 -0.36 0.15 -0.06
-
-0.39 -0.13 -0.26 -0.17 0.47 0.07 -0.40 0.13 -0.57
-
-4.64 -0.09 -3.92 0.07
-
Source: Ref. 118.
no1 concentration under reversed phase HPLC [ Such an effect probably occurs withanthracene also. a result, the values of In k:, derived by extrapolation would be overestimated in comparison with the real values [
The model proposed by Dimov [ experimental data published previously
is based on the theoretical and . The basic idea this
Liquid Chromatography
79
model is to separate the magnitude of a relative retention into two parts. The first part includes one or more parameters that are the most important for retention, which have the greatest correlation with the experimental indices and which therefore give a calculated value of I (Kovats retention index) which is 80% to 120% of the experimental retention value, Iexp.The second part includes parameters which may have low correlation with Iexp but modify the calculated value ofI in a direction towards the Iexpvalue. In the case of separation of nonpolar compounds, this can be achieved if physicochemical properties of the solute are correlated with the chromatographic retention. Structural and geometrical parameters can then be included in the regression, playinga modifying role. These are referred to as intensive parameters, C(IP).The first term is connected with more extensive properties of the solute, C(EP).The second term includes different molecular fragments, which are considered to be responsible for the intensive properties of the solutes. Thus n+k
i= 1
j=n+l
where the various b values are constants, depending mainlyon the stationary phase usedfor theseparation. The subscript i refers to the linear regression betweenIand the extensive properties (EP) of the solute, whilej refers to the linear regression between I and the intensive properties (IP) of the same solute. The following version of model formula (62) was also studied:
I"'
= I(EP)
+ SN
(63)
where SN, the structural number [133], is calculated from a regression equation obtained from the differences between Icxpand the value of the calculated I only, according to theaccepted extensiveproperty:
F - I ( E P ) = bo + bj(IP)
(64)
Molecular mass, number of methylene groups of C atoms (no), different types of topological indices [ 1381, and physicochemical index (PCI) [ 1391 were tested as elements of the first term, C(EP). Different types of structural fragments, such as quaternary or tertiary carbonatoms on the structure of an isoalkane, the distance between alkylsubstituents, etc. [ 1401 were used to produce the correct value ofthe second term, C(IP).The calculation of PC1 needs only the values of the vapor pressure (6,) and the molecular volume ( Vm0Jof the corresponding solutes. Data onthe vapor pressure and the density of the hydrocarbons can be used as a data bank forcomputerized calculation of PC1at any desirable temperature. The structural fragments considered as responsible for the extensive
Chapter 3
80
properties of a given solute are: no, the number of carbon atoms in the isoalkane; nL, the number of carbon atoms in the straight chain(e.g., 3-ethylpentane (3-EP) has no = 7 and nL = 5 ) ; na3, the number of methyl groups in the molecule; and n,, the number of butane chains in the whole molecule. For example, 2,3,4-trimethylpentane (2,3,4-TMP) has ncH3= 5 and nB = 8. The term n, is a topological index introduced in gas chromatography by Altenburg [l411 and used in chemical graph theory [142]. It cannot be considered as an extensive property only, because it is an indication of possible conformation based on the carbon chain. The latter can also be expressed bythe number of Gosh conformers, n G [143]. It was also found that the intercorrelation between n, and n G is reasonable and that the n G can be calculated more easilyfrom the following equation: nG
= nm3
+ ni + n, - 2
(65)
where ni and n,, are explained below. The structural fragments considered as responsible for the intensive properties of the solute (parts of a given molecule responsible for some specific properties, especially when no, n,, etc., are equal), are as follows: n , the number of carbon atoms in the alkyl substituents in an internal position, located after the second carbon atom from both ends of the straight chain (e.g., 2,3-dimethylbutane has ni = 0, 2,3-dimethylpentane has ni = 1 and 3-ethylpentane has n, = 2); nd the number of carbon atoms between neighboringsubstituents (e.g., 3,4-dimethylhexane has n d = 0 and 2,6-dimethylheptane has nd = 3); n,, the numberof quaternary carbon atoms in the isoalkane; n,, the number of tertiary carbon atoms; n,,, the numberof adjacent quaternary and tertiary carbon atoms; and n,,, the number of adjacent tertiary carbonatoms. The final derived equation for theprecalculation in the case of isoalkanes, of I H p L c that gave the best statistics was
IgLc= 41.09
+ 0.92756PC1
(66)
The application of eq. 62 gave the following equation for the SN calculation: SNHpL,
- 6.539na3 + 2.10nL + 6.22nd - 17.90nq - 12.65n, - 12.70nq,
= 10.26
(67)
The results obtained show that the mathematical models expressed by eqs. 62 and 63 are suitable for deriving equations for precalculation ofisoalkane retention indices in HPLC on the reversed phase - 18 column. The most significant structural elements that should be included in the equations may
Liquid Chromatography
81
differ according to the stationary phase. The essential thing is to find the best combination of parameters that should be included in the two termsof the equations. The most important uncertainty concerning the true mechanism of the separation by reversed phase HPLC originate in the experimental data obtained by Colin and Guiochon [ 144,1451. Using pyrocarbon packing, Colin and Guiochon’s results stated that in these circumstances the retention of solute molecules on pyrocarbon packings is due to an adsorption process. If the mechanism of retention on pyrocarbon packings is due to an adsorption process, then the true mechanism on bonded reversed phases moieties become more debatable. Is it an adsorption on the nonpolar bonded moieties or a partition in a stationary phase composed either of the chemically bonded molecules,of solvent moleculesor of a mixture of both. One must first define preciselythe difference between adsorption and partition. Adsorption means the interactions of the stationary phase with the solute or solvent molecules coveringthe external molecular layer of the “adsorbent.” In the simplest case, adsorption is characterized by a monolayer in which the solute and solvent molecules are in competition to cover the external surface of the packing. More often, the interfacial region between the adsorbent and thebulk mobile phasecan be composed of several layers. The separation surface results from an arbitrarychoice and is generally selected in a position such that theGibbs’ surface excess for thesolvent is zero. In a partition process, the sole role of the support is to create a large surface area where the stationary liquid phase will be deposited. The phenomena in the interfacial region are then generally neglected and the partition of solute molecules takes place between the two liquid phases. Each phase contains two components: the solvent and the solute for the mobile phase and the stationary liquid and the solute for the stationary phase. It seems difficult to make a distinction between adsorption andpartition mechanisms. Nakae and Muto [l461 suggested that the retention on Hitachi gel (a styrene-divinyl benzene copolymer) is due a partitionprocess because of the linear variation of the logarithm of the capacity factor with the inverse of the temperature and with the number of carbon atoms in homologous series. This cannot be considered as a characteristic of partition systems because this kind of retention pattern is very similar for both liquid-liquid chromatography (based on partition mechanism) and liquidsolid chromatography (based on adsorptionmechanism) [ 144,1451. In their systematic studies on liquid-liquid chromatography, Locke and Martire [44,147]established expressions for the variation of the loga-
Chapter3
82
rithm of the net retention volume, V,,per gram of packing withthe inverse of the temperature (eq. 68) and with carbon number (eq. 69) for series of homologous compounds: In V, - h; UT
+ RT’a, In V, = a + pn
“
(69)
x;
where is the partialmolar enthalpy of transfer of the solute between the mobile and stationaryphase, a, is the thermal expansion coefficient ofthe mobile phase, a and are constants, n is the carbon number of the linear alkyl chain ofthe molecules, and Tis the absolute temperature. Using the equation
V,=-k’ V, W,
where V, is the mobile phase hold-up of the column and W, the weight of stationary phase, it is possible to obtainequations similar to eqs. 68 and 69 that account for the linear variation in the logarithm of the capacity factor, k’ with NT. The most complete work on liquid-solid chromatography has been carried out by Snyder [ 1481 that using the theory of Locke [44] also derived a linear dependence between log k’ on UT. Several conclusions concerning the mechanism of separation involved in liquid chromatography using nonpolar bonded phases can be drawn from comparative studies of different reversed-phase materials [ 144,1451. These studies suggests that the retention process on thebonded-phase might be more similarto adsorbtion thanto partition.
II. COLUMN PACKINGS Columnpackingsrepresentoneof the most important components of HPLC technology. It is therefore not surprising that numerous reviews deal with both their properties and their applications. This is illustrated by two recent books [ 149,150], that contain much data oncolumn packings. A column packing is composed of a multitude of microparticles arranged into abed. We shall concentrate more on theproperties of the single microparticle rather than on the way they are organized withinthe column. However, due to the constant improvement of liquid chromatography methods, the analyst is nowadays setting hi.gh demands on the stationary phase, selected for thesolution of a particular analytical problem.
Liquid Chromatography
83
Generally, to satisfy these demands, a stationary phase has to fulfill the following requirements: High separation efficiency High selectivity Chemical stability Good peak symmetry especiallyfor basic substancesand, of course Guaranteed reproductibility of theseproperties The types of packings in LSC may be divided into two basic categories: pellicular and porous. Figure 5 shows the basic structure of these materials.
a
shallow-
I
I
+ 0
4-40pm
6
shallow pores C
Figure 5 Types particles used in liquid-solid chromatography (LSC):(a) macroporous; (b) porous layer (pellicular);(c) microbead.
84
Chapter
The large irregularly shaped porous particles (Fig. 5a) are familiar since they have long been used for LSC separations performed in large diameter (1-5 cm) glass columnsat atmospheric pressure. Although the large particle sizes resulted in low pressure drops, separation times were generally quite long. Often the time required for a separation would be several hours or even days. In general, the efficiency of these columns was low since mass transfer in the deep pores and large interparticle channels was slow. Owing to these long analysis times and poor efficiencies, analysts often searched for alternative techniques. With the development of the porous layer beadsor pellicular depicted in the late 1960s, the analyst was now able to achieve high efficiencies since the thin layer of adsorbent permitted a much faster rate of mass transfer. The pellicular particle is comprised of an impervious, rigid central core of about 40 micron in diameter. The outer 1 to 2 microns is a porous shell prepared from alumina, silica, other adsorbent. The relatively shallow pores lead to much greater efficiencies when compared to the large porous particle. However, the thin layer adsorbent on the rigid core severely limits the sample capacity of the pellicular packings. Although the pellicular packings led to the widespread use of high performance LSC, efforts were continued to develop packings which had both high efficiencies and high sample capacities. Following the development of methods of preparing commercial amounts of particles with diameters less than 40 microns with narrow size ranges (Fig. 3c), came the ability to pack these materials and prepare high efficiency, high capacity columns [ 151,1521. These materials gave columns efficienciesalmost two orders of magnitude better than thepellicular packings. Another criterion for classification of HPLC columnpackingsis based on their chemical nature. One speaks about inorganic, organic, and composite packings where the latter have an inorganic matrix carrying an organic matrix. The building materials of the matrices of most packingsare macromolecular substances which include silica (Si02)x(H20)y,alumina (H20),, various modification of carbon (like amorphous glassy carbon or graphite), clay,kieselguhr,diatomaceous earth, celite, and, last but not least, numerous organic natural or synthetic polymers. Silica and alumina are the most frequently used materials. Let us first describe the most important physical, chemical, and chromatographic groupproperties of packings made by different producers. Particle pore size may be from 2 to 10 pm for analytical HPLC. The precise and efficient sizing of packing particles presents a time consuming and demanding operation. It is extremely important to remove submicrometer particles because such fines may block the column end-pieces, detec-
Liquid Chromatography
85
tor cells, and inlet capillaries. Finesalso decrease both column permeability and efficiency. The role of particle size distributionof HPLC packings has not yet been elucidated in detail and the conclusions of various researchers sometimes differ [153]. The importance of this parameter certainly grows with decreasing mean particle size. Usually, the use of narrow size fractions of packings is advised. The role of packing particle shape in HPLC has beendebated at great length. It is now widely accepted that spherical particlesare to be preferred since they Are easierto pack properly Are moreresistant to abrasion and the formation of fine particles Givebedsof generally higher mechanical stability and lower flow resistance The price of spherically shaped particlesis usually much higherthan thatof irregular, angular packings. The pore size of packings allowsa classification into four categories: micropores having diameters( D )smaller than about2 nm, mesopores, with D ranging from 2 to about 50 nm and macropores with D reaching the values from about 50 to about 400 nm. Megapores or gigapores have recently been coined for cavities with diameters above 400 nm. Mesoporous packings dominate in conventional interactive HPLC while macroporous column packingsare necessary to cover the whole separation range of both gel permeation chromatography and the interactive chromatography of polymers as well as for the interactive HPLC on macromolecules immobilized in the pores of packings. Micropores smallerthan about 2nm should be avoided since their presence decelerates the solute diffusion rate and, consequently, causes the column packings efficiency to deteriorate. The pore should have an open and regular, e.g., cylindrical, shape to allow rapid mass transfer and,consequently, high column efficiency. The overall specific surface area of particles includes their external and internal surface areas. The former is rather small but sometimes not negligible. The external surface area reaches a volume of about 0.5 m’g ” for 5 pm spherical particles. The internalsurface area of packings depends on their pore diameter and pore volume and is found to be from 200-500 m’g” for a pore diameter of about 10 nm and about 15-25m’g” for a pore diameter of about 100 nm. Specific surface area is usually measured by the BET procedure based on theextent of nitrogen or argon adsorbtion at 77 K. However, BET procedure does not present an absolute method and the values of the surface areas obtained depend to some extent on the parameters applied in calculations.
86
Chapter 3
Pore volume of packings is a rather overlooked parameter in HPLC. It is evident that a large pore volume of the column packing is important for good selectivity. The large pore volume, however, may also be beneficial for interactive LC: increased pore volume at constant pore diameter means increased specificsurface area and, consequently, raised separation selectivity and sample capacity. The same overall active packing surface area can be reached with a column with smaller dimensions when packed with materials possessing larger pore volume. This means that both the working pressure and the eluent consumption are decreased in comparison with conventional packings. Conversely, at the same overall packing surface area and column size the pore diameter of packing can be increased, resulting in better mass transfer, especially for macromoelcules. The high pore volume of packing, unfortunately, also brings about the risk of increased fragility and sensitivity of the column packing to elevated pressure and therefore, a compromise should be looked for. The pore volumes of the majority of common silica gels range from 0.5-1.5 cm” ” but we show that the latter value need not be a limiting one. The mechanical resistance of a packing particle to both abrasion and the action of ultrasonics is important in reducing the formation of fines during transportand in manipulation both before and during column packing. A pressure resistance of at least 10 MPa is necessaryand good HPLC packings will usually withstand pressures at high as 50 MPa. Pressure pulses are especially exacting during column packing and flow interruption, e.g., during sample injections, column switchings, etc. Both the swelling resistanceand thethermal stabilityof organic polymer based column packings are rather low. The so-called two-step crosslinking of organic gels increases their mechanical and swelling resistance. However, the excellent properties of silica gel and carbon particles in this respect havenot yet been equaled. Both batch-to-batch repeatability and producer-to-producer reproducibility and compatibility of packing properties can be regarded as the weakest points of silica gels. Differencesin retention behavior existnot only among columns from different manufacturers, but also between different column lots from the same manufacturer. In a study of Sander and Wise [154], the chromatographic properties ofmore than 25 commercial C18 phases werecompared. No two columns were exactly alike, and most varied considerably in both absolute retention and selectivity. The interstitialpackingporosity is defined as the ratio of the interparticle volume within the packing bed to the total bed volume. Interparticle volumes of conventional HPLC columns range from about to about 55% of the total column volume. Obviously, the interstitial packing bed
Liquid Chromatography
87
volume cannot be utilized for separations; therefore, one of the challenges for research in the field ofHPLC is to find a way of reducing it. The overall macroheterogeneity of the packing bed means the presence of the larger irregularities in the bed structure, e.g., channels and cavities. It results in excessive mixing ofthe mobile phaseand consequently in decreased column efficiency.The intrinsic properties of packing particles and the way they are packed into the LC column may both be responsible for macroheterogeneity of the resulting bed. The surface properties of packings must often be modified by chemical and physicochemical procedures suchas grafting, endcapping, and coating by low molecular or macromolecular substances to ensure the appropriate separation mechanism,wettabilitywith eluents, biocompatibility, etc. Certainly, the materials far prepared present neither ideal nor universal HPLC column packings. Therefore, further research and development is needed to synthesize better basic materials which can be chemically modified, and thus will provide with highly specific, tailor-made HLPC column packings. We believe that several other problems should also be solved, for example: The synthesis of nearly monodispersed microspherical silica gels of different mean particle sizes as well as different mean pore sizes and pore size distribution, preferably with a sponge-like porous structure and with large pore volume combined with good mechanical stability Continuous production of silica gelsand other packings at lower cost and with improvedrepeatability of their properties The synthesis of composite packings in which the pores of mechanically stable matrices are filled witha network of soft, slightly crosslinked macromolecules The synthesis of packings with improved mass transfer, such as pellicular materials witha thickporous layer, crazed materials, etc. The preparation of homogeneous and stable beds of packings that have reduced interstitial volume In addition to the conventional packings made from silicon dioxide, alumina, and organic polymers, new types ofmatrix building materials such as carbon and nonoxide ceramics deserve increasedattention.
A. Silica BasedPackings In spite of the chemical instability of silica in basic media and of the presence of residual acidic silanol groups [ 1551, it still remains the most popular LSC packing because its uniform pore structure leads to columns having
88
Chapter
much greater efficiency than polymeric columns which have a somewhat irregular structure [156]. Most of the silica based packings are technical grades and were not specifically designedfor high quality preparative separations. Silica gels with different pore sizes and pore size distributions (Table 6) can be readily prepared; however, SiOz basedmaterials with small pores in the range of 4-6 nm and with naarrow pore size distribution and large pore volume have not yet been described. A pore diameter of about 10 nm accounts for the majority of separations of solutes of M < 2 kdaltons. For larger molecules (oligomers and high polymers), pore diameters of approximately 30 nm and more are preferable in order to overcome the low diffusivities. Mesoporoussilica gelsof controlled porosity can be prepared by many conventional or newer procedures, for example, by [157,158]: (1) agglutination of the sol particles(globules) of polysilicic acideither directly [ 1591 or in the presence ofthe appropriateorganic resin [ 1601 that is subsequently removed by ignition; (2) agglutination of nonporous solid microparticles of Aerosil [163], gelation of silicic acid released from solutions of its salts (e.g., sodium silicate) by changing the pH of the system. Silicic acid condensatesand forms oligomers, and, subsequently, crosslinked high polymers. In the stage of oligomer formation, the phase separation can be allowed to start that a partly spongelike structure arises [ 1641, (4) twostep polycondensation ofthe silicic acidand released from polyestersilicates [ 165,1661. It seems that this procedure also allow the inclusion of phase separation steps and the generation of spongelike structure. In the course of the last two processes large pore volume, mechanically stable silica gels are formed. The spherical shape of particles is obtained when processes (l), (2), and (3), described above, are performed within microdroplets of material dispersed in an appropriate liquid dispersing agent or in air. The most commonliquiddispersing agents are nonpolar organic solvents for the processes (1) and (3) and aqueous-alcohol for theprocedure (4). Macroporous silica gels can be prepared by the agglutination of large silica sol particles, by controlling both the polycondensation processesand hydrogel drying or, finally, by modification of either silica hydrogel or xerogel. The best known procedures for pore size enlargement include sintering and as already mentioned, hydrothermal treatment of xerogels. Simultaneously withthe enlargement or silica globules, however,the sorbent pore volume drops, especially in the case of silica gel sintering. Moreover the hydrothermal treatment is not very repeatable. On the other hand, the recently developed controlled chemothermal modification of either hydroor xerogels has very good repeatability when used to produce the sponge-
Liquid Chromatography
89
like structured silica-gels with large pore volumes, with extremely narrow pore size distributions and with arbitrarily controlled mean pore diameter [ 1671.
In the early 1970s the Lanzhon Institute of Chemical Physics, Academia Sinica, developed different varieties of silica packings for NPHPLC, such as pellicularsupport (coated glass beads witha thinlayer of silica) and aggregated porous silica [168-1711. These packingsare commercialized and supplied by the Shangai First Reagent Plant and by Quingdao Chemical Engineering Plant (Table 7) [ 1721. Performances of YWG microparticulate silicawas studied extensively by many Chinese chromatographers [1731751.
Some of the properties of silica can be explained bydifferent reactivitiesof the various silanol adsorption sites. Of particular interest is the small population of very strong adsorption sites that can exert a currently underestimated influence on the surface properties. The origin of these unwanted silanols may emanate from the silica structure itself or may be explained bythe presence of trace metal impurities. The silica surface consists of various kinds of silanols and siloxanes. The silanols are considered to be strong adsorption sites whilethe siloxane sitesare usually regardedas hydrophobic [157]. The 6 bonds in the Si-0-Si moiety are strengthened by d,-p, interaction. Both lone pairs of electrons on the oxygen atom are involved in an interaction and that means that the silane sites on the silica surface cannot form hydrogen bonds with adsorbates [ 1761. It has been shown chromatographicallythat siloxane groups contribute little or nothing to solute retention [ 1771. Silanols on the surface can exist in single, geminal, or vicinal forms. A pair of vicinal silanols can form a so-called bonded pair and it has been suggested that geminal silanolscan also form abonded pair [ 1781. The classical approach in assessing silanol activity is. tomeasure the adsorption of a polar solute in a nonpolar solvent environment. In 1950 Shapiro and Kolthoff [l791 measured the uptake of methyl red on thermally aged silicasto study the effect of heat treatment on silanol activity. Scott and Kucera [ 1801 developed another NPHPLC procedure for assessing silanol activity. They measured the retention of benzene and nitrobenzene on reversed phase columns usingdry heptane as the mobile phase. For columns with low silanol activity, nitrobenzene was observed to elute only slightlyafter benzene, while greater activity resulted in increased nitrobenzene retention. Welsch [ 1811 and coworkers examinedthe normal phase retention of several polar samples including nitrobenzene and correlated this retention to silanol concentration values determined from reaction of the phase with
Chapter
90
Table 6 Silica BasedPackings used in Normal Phase Liquid Chromatography Name
Supplier
Matrex Silica media XWP XWPlOOo XWP1500 A Bakerbond
Amicon Grace Amicon Amicon Amicon Baker
Bio-Si1 HA Bio-Si1 A
Bio-Rad Bio-Rad
-
ICN
-
A A
ICN Silica
dp(clm)
-
as(m2g 540
-
ICN
KC Microperl M.
Kali Chemie
KC Microperl L Nucleosil Polygosil60
Kali Chemie Macherey-Nagel Macherey-Nagel
-
60 40 500
-
550 550
ICN Silica N
pf/(nm)
-
-
-
-
-
-
-
-
-
-
-
4 4
Polygosil
Macherey-Nagel
Kieselgel40
Merck
Kieselgel60
Merck
Kieselgel
Merck
LiChroprep Si40
Merck
-
LiChroprep Si60
Merck
-
-
-
Liquid Chromatography
91
Table 6 Continued Name
Supplier
dphm)
as(mzg")
LiChroprep Si100
Merck
15-25 40-63 37-75 75-125 37-75 75-126
-
Millipore Waters Millipore Porasil B Waters Millipore Prep-PAK Waters 500 silica Separations Vydac TP silica group Separations Vydac HS silica group Whatman LPS-1 Whatman LPS-2 Chromegasorb 60R ES Industries Tracor Chrom Sep SL HiEff MicroPart Applied Science Laboratories Lichrosorb Si-60 Alltech Associates MicroPak Si Varian Associates Aerograph Partisil Altex Scientific RSL Silica RSL Si1 60 Chrompak Silica A Perkin-Elmer Sil-X-1 Perkin-Elmer Hypersil Separations group LiChrospher Si- 100 Glenco Scientific Spherisorb SW Chrompack Spherosil XOA600 Chrompack Super Microbead Si Fuji Davison Chemical Ltd. Zorbax Si1 E.I. DuPont de Nemours SI Polymer Institute, Bratislava, Slovakia
Porasil A
dp = median pore diameter;
Source: Refs. 161, 162.
300-500
-
-
-
140-230
-
-
55-105 20-30
-
-
80
30
20-30
500
8
13-24 37-53 10 5-10 5-10
250 450 500 400 250
4-6
5-10
500
2-6
5-10
500
2-4
5-10 5-10 5-20 13 13 7
400 200 500 400 400 200
2-4 2-4 2-4
5-10
370
2-4
5-10 5-8 5-10
220 550 380
4-6 4-6
6-8
300
2-6
200
25
= surface area;p d = pore volume.
-
5
-
2-7
-
-
Chapter
92
Table 7 Silica Based HPLC Packings Manufactured in People's Republic of china" name First
Trade
Shangai PSG-l 25-37 PSG-2 PSG-3 Chemical Beijing 3-7 250-280 Aggregated SiOz Engineering Plant 3-7 300-350 Aggregated SG 00 YWG Spherical SG DG 1 DG 2 DG DG 4 YWG 1 YWG 2 YWG YWG 4
Surface area Particle size (m2/g) (W) 2-3 Plant -7 Reagent
300 350-500 125-500 25-45
-
-
Manufacturer
35-50
-7Ocean Quingdao 200Chemical mesh Engineering Plant - SecondTianjin - Plant Reagent Chemical
-
5-25 5-25 5-25 5-25
"1 thankMr. P. Lu from Beijing Technical University who facilitated my direct access to the Chinese scientific literature.
methyl lithium. Benzyl alcohol was found to be most sensitive compound to silanol activity. Small changesin silanol concentration resulted in larger changes in benzylalcohol retention compared to the other solutes studied. In addition, Walters [ 1821 proposed another reversed phase test to assess silanol activity. This test is based on the retention of N,N-diethyl-mtoluamide relative to anthracene in an acetonitrile mobile phase. A variety of procedures can be used to determine the surface concentration of silanols. Isotopic exchange with D20 is considered to give the most reliable results [ 1831. Titration of the silanols with NaOH in the presence of saltscan also be used [ 184,1851. The most reliable methods of determiningthe surface silanol concentration give values of 8 i 1.O pmol/m2 andthis value is generally accepted. The existence of various forms of silanols on asilica surface has been proved by"Si CP-MASNMR in a number of papers [ 184,1851 and it is generally assumed that different kinds of silanols will react with different strengths. Adsorption and reaction capabilities of silanols also have been investigated by adsorption and spectroscopic methods but the results appear to be contradictory. The investigations based mainly on IR spectroscopy postulates that isolated silanols are much more pronounced adsorption sites than bonded
Liquid Chromatography
93
silanols which are capable of adsorbing water only[ 1861. Maus and Engelhadt [ 1871 have shown by FTIR that molecules with basic properties are adsorbed preferentially on acidic, isolated silanols, whereas solutes with hydroxyl groups are able to interact with vicinal hydrogen-bonded silanols and areadsorbed on these sites. They alsofound that only isolated silanols react with chlorosilanes.Donor molecules, especially those containing lone pairsofelectrons, adsorb preferentially on the freelyvibrating groups whereas the hydroxylated moleculesadsorb preferentially on the hydrogenbonded hydroxyls[ 1881. Earlier IR results showedthat physical adsorption takes place on freely vibrating silanols [ 1891. This observation is of great importance for themodification of silica surfaces since physical adsorbtion on the hydroxyl group must precede the reaction of the modifier [ 1881. It has also been reported that the introduction of boron atoms onto the silica surface increasesthe acidity ofthe remaining silanolgroups [ 1901. All these papers give a consistent picture ofthe adsorption properties of silica residing mainlyin the isolated silanols. On the other hand, Snyder and Ward [l911 state the opposite, i.e., that vicinal hydrogen-bonded silanolsform the so-called “reactive silanols” that are more reactive than single isolated silanols. The idea of “reactive silanols” was substantially supported by various workers [ 192-1941, using crystallographic or spectroscopic methods. A strong confirmation of the silanediol hypothesis has been published showing that theselective blocking of geminal silanols with Fe3+ ions greatly reduced adsorption of amines and increased the number of column plates more than threefold [ 1951. Total surface concentration of geminal silanols was 0.37 pmol/m2 but only 40% of them influenced the retention time of diphenylamine hydrochloride confirmingthat silanols cannot all be treated as equivalent to each other. The paper Dreist and Ritchie [l961 again stresses the controversy over geminal sites; they claimthat anenrichment of the surface with geminal sites before modification is essentialto obtain well-deactivated bonded phases on the grounds that only one silanol group of a geminal site can react with an octadecylsilane but the other one becomes inaccessible to a solute molecule. Thus the more geminal sites there are on the surface the more inaccessible sites thereare after modification [ 1971. There is IR spectroscopic evidence available to support the hypothesis of the higher reactivity of geminal sites. Hair and Hertl [ 1971 were the first to report that the IR adsorption band at about 3750 cm ”, ascribed to the freely vibrating OH group on silica is composed of three bands at 3751, 3754, and 3743 cm as shown in Fig. 6. The contribution of these wave numbers are 18070, 61 070, and ,21070 of the total absorbance. The high and medium absorbance bands were found to disappear much faster than the
Chapter
94
a
Figure 6 Expandedbandspectrumdue to freely vibrating hydroxyl group. The uppercurve is theobservedspectrum,thelowercurvesaretheresolvedbands composed of symmetrical, Lorentzian shaped bands. (From Ref.197.)
lowfrequency band at cmwhen reactedwithchlorosilanes. The central band was ascribed to simple hydroxylgroups on thesurface and the other two bands to geminal groups. The splitting of the cm “I band into three has been confirmed by others but explained in a different way [ The low frequency band was assigned to silanols slightly perturbed by neighboring lattice oxygen atoms while the higher frequency bands were said to be due to splitting of the isolated hydroxyl band into two by a coupling phenomenon. Both these investigations were carried out on fumedsilicasamples,i.e., Cab-0-Si1 [ and Aerosil [ All the preceding results show that the silica surface may contain a variety of adsorption sites, the most important of which are silanols. In viewof the evidence discussed above it is likely that internally bonded geminal groupsform some ofthe most reactive sites. Thermal removal of geminalgroups indicates that not all the geminal pairs are hydrogen-bonded. Reactivity ofthe silanols dependson their acid-
Liquid Chromatography
95
ity with hydrogen-bonded geminal groups being perhaps more acidicthan isolated silanols. Thus isolated silanols should show a lower reactivity than geminal pairs but higher than hydrogen-bonded vicinal silanols which, according to IR studies, are weak adsorption sites. Since a large proportion of geminal sites seemto be hydrogen-bonded withadjacent silanol and can abe thermally removed, it is not valid to regard them all as identical. The acidity of particular silanolson absolutely pure silica would depend, mainly on theirenvironment and theirability to hydrogen bond. However, in reality, there is no such thing as absolutely pure silicaand even very small quantities of impurities may greatly influencethe acidity and consequently the activity of surface silanols. Chromatographic-grade silicas usually contain 0.1-0.3%of metallic impurities. These small quantities of metallic impurities are often neglected and variations in performance are explained in terms ofthe intrinsic properties ofthe silica but it has to be emphasized that even a very small population of strongly active sites can influence considerably the chromatographic propertiesand can accountfor a third of the retention [ 199,200]. Dependingon theprocess usedto prepare the silica, a trace amount ofvariousmetalscanbeincorporated into the matrix. Silicas prepared from commercial sols are reported to be more prone to metal contamination than silicas prepared from alokoxysilanes [201]. The determination of sodium, aluminium,and iron levels leadto the conclusion that the presence of iron and other metal contaminants is thought to cause peak tailing and reduced column efficiency, particularly for chelating solutes such as beta-diketones, phthalates and proteins. Verzele and coworkers [ 199,200] have investigated the effects of metal contamination on chromatographic performance and have developed a test for metal activity based on the retention behavior of 2,4-pentanedione. This compound is essentially unretained on columns with low metal content. For columns prepared with metal-contamined silica, however, acetyl-acetone (2,4-pentanedione) is retained and peak shape is poor. It should be noted that trace metal activity is distinct from silanol activity. A column can be well-deactivated (low-silanol activity), but still exhibit unacceptable metal activity. Metalcontaminant can be removedfrom the silica matrix by multiple reflux operations in mineral acids [202]. Metal activity after such treatment is markedly decreased as indicated byan acetylacetone test. Although acid washing usually improves the quality ofthe silica itcan sometimes havea detrimental influence on the surface activity, if the silica contains appreciableamounts of aluminum stabilized byappropriate quantities of sodium cations. Acid washing may remove the sodium only leading to the formation of sites of high adsorption even catalytic activity according to the following structure
96
Chapter Na
The difficulty in removing aluminum has been reported previously where gaseous extraction of gas-chromatographic supports (Chromosorb W, G , and P) removed onlyabout a quarter of the aluminum while extracting iron almost completely [204]. There is considerable difference in the trace of metal concentration reported for silicas used as packings in liquid chromatographic columns [205,206]. Metals in silicagel have often been blamedfor causing strong adsorbtion of nucleophilic organic compounds. The adsorption differences between pure pyrogenic silica and chromatographic silica were attributed to the trace metals present in the latter [207]. As demonstrated above, trace metallic impurities are a probable source of additional adsorption sites on silica and, although they may not interact directly with analytes, they increase the activity of neighboring silanols. Any additional adsorption sites created are of an acidic nature and adsorb or even chemisorb basic compounds. Although knowledge ofacididbasic sites on the surface of silica is still limited, much more is knownabout acidic sites than basic ones partly because more compounds with a basic, nucleophilic nature are chromatographed than those withan acidic, electrophilicnature. The mechanism by which acidic(or basic) sites are generated in catalysts is well-known and it is mainly from this literature that explanations for their generation in chromatography must be sought. Silica gelwith impurities in it can be considered to be a mixture of at least two oxides MO;SiOz, with the latter being the main constituent. The impurity oxides are contained within the silica matrix so the material is a chemical rather than a mechanical mixture. Two hypotheses in catalysisare known for the generation of acidityin chemically mixed oxides.The first, due to Thomas [208], states that the source of the acidity is oxygen valences unsatisfied by the coordination metal. The second, due to Tanabe et al. [209] can be used to predict Brsnsted or Lewis acidity and has been validated by these workers in 90Vo of binary oxide systems. According to Tanabe’s hypothesis, chemically mixed oxides with SiOz as themajor component should be acidic if they containthe following elements:AI, Ba, Be,Ca, Sr, Ti, and Zr. Many of these elements are present in chromatographic grade silica. Particularly deleterious are the multivalent metals such as the lanthanides, aluminium, titanium, and zirconium that can generate sites with a high acidity. The acidity of the material usually increases with the increase in trace metal content but there is no exact correlation between the two. The maximum
Liquid Chromatography
97
acidity is observed for a binary system of oxides when the amount of one oxide is muchgreater than the other. In chromatographic grade silica the situation is more complicated by the fact that thesilica matrix contains a variety of metals. Different metals not only generate different amounts of acidity but also sites of different acid strength.
B. Silica Bonded Packings The development of column packings with covalent bonded phases is one of the factors thathas ledto the explosive growth ofHPLC during the past 20 years. Estimates of current use indicates that about three-fourthsof all separations are now carried out with columns of these chemically bonded stationary phases. The surface of silica gel is characterized by the presence of four types of surface groups Three of these are silanol groups and the fourthis made up of siloxane bridges formed from condensation reaction between adjacent silanol groups. The silanol groups are hydrogen bonded (to an oxygen atom in an adjacent silanol group), reactive (by virtue ofsuch hydrogen bonding to the silanol oxygen atom) or free. The relative positions of the different silanol groups depend upon the method of preparation of the silica and on its subsequent treatment but are related to its average pore diameter. The silica usually used in liquidchromatography has mostly free silanols and in the fully hydrated state bears approximately six groups on each square nanometer of itssurface [21l]. Four types of process have been employed for thesynthesis of bonded phase packing materials. These lead to the formationof (1) silicon-oxygensilicon-nitrogen-carbon,and silicon-carbon, (2) silicon-oxygen-carbon, (4) silicon-carbon bonds. 1. To form bonded phase packings with Si-0-Si-C bonds, silica typically is reacted withfunctionalized silanes accordingto
= Si-OH
+ Six,&-,
+
= Si(OSiX,-,R,-,)
where X is a reactive group such as alkoxy or halide, and Rcommonly is an alkyl or substituted alkyl group. This reaction creates siloxanebonds between the silane and thesilicon atoms of the solid supports, resulting in a stationary phase where the R groups of the silane largely determinethe chromatographic behavior of the column packing. There are twomaintypesof reactions possible from the general scheme of eq. 72. The first type, presented in Scheme 1, uses a monofunctional silane (n = 1) that produces a surface where the silane covers the
98
Chapter
=
p
Scheme 1 Schematic representation of the bonding
monofunctional silanes to
a hydroxylated surface.
silica as a monolayer. The advantages of this reaction are that it is reproducible and convenient; the resulting surface of monolayer coverage exhibits excellent mass-transfer properties that produce high column efficiency for most solutes. The second typeof reaction uses di-or trifunctional silanes (n = as shown schematically in Scheme2. If the reaction is carefully controlled to exclude water, the resulting monolayer-type surface generates high column efficiency (upper portion of resulting compound in Scheme 2). How-
Scheme 2 Schematic representation of the bonding of polyfunctional silanes to a hydroxylated surface.
Liquid Chromatography
99
ever, there are potential problems withthis approach. A less than 2 equivalent of X-functionality per mole of silane can react with SiOH groups on the silica surface [212,213]. A novel synthetic approach to produce chemicallybondedsilicapacking containing Si-0-Si-Cmoiety involves the preparation of a silica intermediate [214] containing stable silicon hydride (silane) surface species followed bythe catalytic addition of theseorganic compounds bearing a terminal vinyl group. The overall synthetic scheme for silica silanization generally involves several steps, as shown in Scheme 3. A prebonding reaction is carried out to prepare the silanizing agent, usually viacatalytic addition of a SiH group to a terminal olefin (hydrosilation). The primary silica derivatization reaction involves the nucleophilic attack of surface silanols at thecentral silicon atom of the silanizing reagent.Additional silanization of the modified support (end-capping), this time with trimethylchlorosilaneor hexamethyldisilazane, is usually carried out to somewhat reducethe surface concentration of unreacted silanolsleft by the primary bonding reaction. A cursory look at the reaction Scheme reveals that by using the prebonding step 1, an alternateSi-C bond can be formed directly between the silica surface and the organic group: -O\ -0/ -0-
0
-
H
surface hydrosiloxnne
+ H2C terminal olefin
0
\
-
Si-CH2
- CH2 -
0' surface. organoslloxane
(73)
Since the two bulky methylgroups will no longer be present, this alternate reaction should result ina closer packing ofthe anchored organic groups as well as a more stable bonded phase. Naturally, this latter procedure would require that silicon hydride species were already present on the solid support and the heterogeneous hydrosilation reaction proceeded witha good yield. 2. This type of bond is formed by the esterification of the acidic silanol groups with an alcohol. Two processes have been used for this synthesis. One [215] involved heating silica gel with excess alcohol under pressure at 28OOC for 12 h while the other [216] employed chlorination of silica gel by treatment with thionyl chloride in refluxing benzene for 12 h followed by reaction of the silica chloride with excess alcohol in the presence of pyridine for 4 h at 8OOC. The latter process gave material with 0.5 milliequivalents per gram(mEq-g") of bonded phase. This suggested that only two ofthe silanol groups on each square nanometer had reacted and it was postulated that the remainder were preventedfrom taking part by steric effects or possibly the lesser reactivityof some ofthe types of silanolgroup.
100
Chapter 3
-R
.cat.
I
toluene
I
-
-\/Si -OH
0\
+
y43 Cl - S i -CH2 I
-/Si-0- CH2 - R
0 Toluene
<Si
W4
7% %-CH2
- CHI-
R
- OH
-/ Si -OH 0
-I\Si -OH 0 \
7s-
CH3
+
fl-
I
l
PY
-
toluene
OH
OH
0OH OH
0-
0 -
-
-
-R
Scheme 3 Typical reaction for the silanizationof silicas: (1) prebonding reaction (presilanizing agent);(2) primary bonding reaction;(3) “end-capping.”
Liquid Chromatography
IO1
The preparation of these bonded phases is relatedto that used for esterification. A primary amine is allowed to react with silica chloride in a dry solvent between 60 and 12OOC for 8 to 10 h. The yields of a number of such reactions with a variety of amines ranged between 5 and 20% of the total possible and varied with the nature andsize of the amino compound used. The product this type of synthesis are stable for organic solvents and aqueous media between pH3 and 8. 4. These packings are prepared by reaction of silica chloride with organolithium [216] or Grignard [217] reagents. The Grignard reaction involved treatment of silica with silicon tetrachloride in pentane followed by a reaction with an excess of naphthyl magnesium bromide. Approximately four bonded groups per .mz of surface were obtained. Reactions of this type rarely have been used for the preparation of bonded-phase packings. The types of bonded-phases summarizedin paragraphs (1)-(4) above can be obtained as monomeric adsorbents (reaction with one molecule, grafted to the surface) and as polymeric adsorbents when a multilayer and/ or crosslinked coating is made, and these typesare considered below. Monomericphases are the most widely used. The efficiencies are much greater than those obtained with polymeric phases because of the faster diffusion rate in the stationary phase. The preparation reaction is carried out in an absolutely dry solvent (generallytoluene) under prolonged reflux and thehydrogen chloride is removed continuously by bubbling pure nitrogen through the mixture. When the reagent is a di- or trichlorosilane, the absence of water is imperative in order to avoid crosslinking polymerization reactions. With monochlorosilane, it is obviouslyimpossible for polymerization to occur. A variety of proceduresare described inthe literature [150,151]. The bonding reactions listed above give routes by which a few simple groups may be attached more or less permanently to a column packing material. The method themselves, however, limit the range of functional groups which may be incorporated in the bonded phase. Secondary reactions are necessary in order to synthesize phases that contain other functional groups. Various types of HPLC column packing materials were newly prepared [218-2231 and examined for their ability to separate vitamins [224], polyaromatic hydrocarbons [225], cyclohexane derivatives [226], and other organic compounds [227]. Several studies [228,229], have shown that certain liquid crystals or structurally similar compounds when bonded to a polysiloxane backbone retain or develop liquid crystalline behavior. The use of liquid crystals as stationary phases in gas chromatography was first established over25 years
102
Chapter3
ago and a typical reviewmay contain hundreds of references [230]. In contrast, the early studies [231,232],using liquid crystals as stationary phases for HPLC were rather incomplete, and no conclusioncould be drawn about their potential usefulness. There is, however, one important difference between the use of liquid crystals as stationary phases in gas chromatography and liquid chromatography. In gas chromatography the liquid crystal can be coated directly on a solid support or capillary wall. The low volatility of these materials leads to long column lifetimes. In HPLC such a procedure would result in rapid loss of the stationary phase due to solubility in the mobile phase or to removal by shear forces. Therefore, the only practical solution for HPLC is to produce a chemically bonded material that possesses liquid crystal properties. For example, [4(allyloxy)benzoyl]-4-methoxy-phenylbonded to a polysiloxane backbone yields a new HPLC packing that possesses retention properties in organic and aqueous mobilephases[233]. In addition, the synthesis of a cyclam (1,4,8,1 l-tetraazacyclo-tetradecane) wasdescribedbyBagnoud [234] and the reaction scheme for thesynthesis ofthis material is presented in Scheme 4. The most popular and typical alkyl bonded silicais octyl- and octadecy1 silica bonded phases. Various methods have been described [235-2371 for the preparation of these bonded phases, with the object of improving their stability and efficiency.Among other factors suchasalkylchain length, surface coverage, and endcapping, the properties of bonded phases have been shown to depend on the reaction medium [238] and the functional group of the silanizing agent [239]. The chromatographic performances of these materials has been reported by many authors [240-2481. In order to convertsilica gel into the hydrocarbonaceous bonded phase it is usually reacted with an alkyl-trichlorosilane [249-2531. Treatment of the porous silica with di- or trichlorosilanes, for example, octylmethyldichlorosilane, results inthe formationof polymeric phases in which the alkyl groups are attached to the silica surface via siloxane bonds. Unreacted halogen atoms are hydrolyzed by traces of water present in the reaction medium and thenewly formed silanols can either undergo condensation reaction with surface hydroxyl groups and/or react with morehalogenated silane molecules to produce the crosslinked polymeric phase. Apart from the above reaction mechanism, a new,densepolymer layer can be built up the silica surface by exhaustive silanization under controlled conditions resultingin a multilayerof the desiredthickness [253]. In this case, after the initial silanization and subsequent hydrolysis of the unreacted functional groups of the organic moiety, the modified silica is again silanized withanother portionof the starting silanizing agent to form a second layer and on. The structure of the final is that of an
Liquid Chromatography
I03
+
P +2?
I I I
0
0
0
104
Chapter
Scheme 5 The structure bonded-silica obtained by repeated silanization; R' = CH,; R = CH,-(CHz),- and n = 0, 1, 2, etc., depending on the number reaction steps.
oligomer made up of repeating units of the silanizing agent as shown in Scheme 5. Another possible reaction mechanism between silicaand bifunctional silanes under anhydrous conditions is that of silane molecules with two adjacent surface silanol groups to form a closed ring of siloxane bonds as shown in Scheme 6. While both reactionmechanisms are possible, the reaction shown in Scheme6 is sterically unlikelyto occur and if it actually takes place, it can be viewed as a terminating step since all the reactive functional groups of the silanizing agent are covalently bonded during the first reaction. Consequently, subsequent treatment of the bonded silica with more silane molecules will result in littleor no change in the carbon loading. Similar bonded phases composed of CZ-C,, hydrocarbonaceous moieties as well as aromatic ligands have been also introduced. Thus, a variety of hydrocarbonaceous phases are available with various particle sizes and shapes. Some bonded phases with CzH,CN functions can also qualify as nonpolar stationary phases under certain conditions. In most cases the actual surface topology of these materials on the molecular level is not known. The hydrocarbonaceous chains may form a
Scheme 6 The possible structure drous conditions.
a silica-bonded phase synthesized in anhy-
I05
Liquid Chromatography
Figure 7 Illustration of the molecular structure consisting of the hydrocarbonaceous functions, R , covalently bonded via siloxane bridgesto the silica surface.
molecular fur bound to the surface (Fig. 7 ) . Nevertheless, due to the poor wetting of the nonpolar moieties by polar solvents it is unlikely that the hydrocarbon chains would fully protuberate into the mobile phase. In other cases the silica surface may be covered by a poly-alkylsiloxane layer as schematically illustrated in Fig.8 [254]. It is recognizedthat the carbon content of alkyl-silica isan important
I
H0 - Si - OH ,Si,
d
I
I
I “O-7-O i/- sL 0 0 OH 0 I
1
I
-Si-0-Si-0-Si-0-Si-0-SiI I I I Silica surface
I
I
Figure 8 Schematic illustration of the poly(alky1-siloxane) coating in a pore of siliceous stationary phase. The polymer is covalentlybound to the surface.
106
Chapter
Table 8 Packings for Reverse Phase Liquid Chromatography
Name Matrex silica Media C8 C18 Bakerbond Methyl Ethyl Butyl, hexyl Octyl Octadecyl Phenetyl Diphenyl ICN Silica RP-8 ICN Silica RP-l8 Nucleosil 3OCl8
Supplier
Amicon Grace Grace Grace Baker Baker Baker Baker Baker Baker Baker Baker ICN ICN Macherey Negel Polygosil 60C8 Macherey Negel Polygosil 60C18 Macherey Negel Prep-PAK Millipore Prep-PAK Millipore Bondedpak Millipore Vydac C18 Waters Porasil B Waters Kieselgel60 Merck Lichroprep RP-2 Merck Lichroprep RP-8 Merck Lichroprep RP-l 8 Merck Vydac 201 HS Hewlett Packard Vydac 201TP Hewlett Packard Vydac 214TP Hewlett Packard Vydac 219TP Hewlett Packard Sychroprep RP-PC18 Synchron Sychroprep RP-PC8 Synchron
Particle size (pm) 20,30 50, 105
-
40
-
-
-
18-63 18-63 30 25-63 25-63 30 50-105 30-75
-
63-200 25-40 5-20 5-63 20-30 20-30 20-30 20-30 30 30
Specific surface area Pore diameter (m2g") (nm)
107
Liquid Chromatography
Table 8 Continued
Specific Particle surface area Pore diameter Name Sychroprep RP-PC4 Sychroprep RP-PC1 Backerbond diol Backerbond cyanopropyl DNPG-ionic DNB Leu-kovalent Lichroprep Diol Lichroprep NH2 Lichroprep CN S I NH2 S I CN
size Supplier
(pm)
Synchron Synchron Backer
40
Backer
40
(m'g")
(nm)
-
Backer
Backer Merck Merck Merck Polymer Institute, Bratislava, Slovakia
-
property of such stationary phases as it can greatly influence their chromatographic behavior. The knowledge of the carbon content of the hydrocarbonaceous ligand and the stationary phase together with the specific surface area of the silica, however does not give sufficient information on the actual surface coverage.Thisisbecause the specific surface area is usually obtainedfrom BET measurements[ 2 5 5 ] , and, thus, includes micropores which maynot be accessibleto the silanizing agent but whose surface can constitute a large fraction of the specific surface area of the silica gel proper. A variety of nonpolar bonded phases are commercially available(Table 8 ) ; unfortunately their detailed specifications have not been disclosed. Most recently, Yu and Hartwick [ 2 5 6 ] have demonstrated the advantages of using predesigned heterogeneous bonded phases with hydrophobic and ionic propertiesfor theseparation of biopolymers. These silica-bonded materials incorporate anionic, cationic, as well as hydrophobic/hydrophilic sites in a single stationary phase. By cobonding a mixture of hydrophobic and zwitterionic ligands onto silica, it is possible to develop universal stationary phases for the separation of solutes with diverse functionalities including neural, anionic, cationic, and zwitterionic molecules by manipulation of the ionic strengthand pH of the mobile phases. The synthesis of bonded zwitterionic supports removes many of the
Chapter
108
'
practical limitations of zwitterionic pairing such as long equilibrium times and poor reproductibility under gradient elution conditions while retaining the desired chromatographic properties. The synthesis of zwitterionic packing is based onto a bilayer scheme in which a silane with a versatile terminal reactive group was first bonded onto the silica to yield a reactive substrate. A second compound with the desired chemical functionalities was then reacted with this substrate to form the final stationary phase. This second compound can be complex and can be the product of any set of prior syntheses not usually compatible with silane chemistry. In Scheme 7 are presented three starting bonded silica. Many permutations of zwitterionic bonded stationary phases were synthesized by using these three reactive bonded substrates. These included chiral/ achiral strong zwitterion-exchange (SZX) supports and chiral/achiral weak zwitterion-exchange (WZX) supports (Scheme 8). The hydrophobic strong zwitterion support (hydrophobic SZX) are sufficiently hydrophobicto function as a reversed phase material.The chromatographic behavior of these materials suggest that thehydrophobic zwitterionic bonded phasesare very versatilesupports that function as universal support materials. Careful manipulation of the eluent composition and pH makes it possible to use these supports alternately as reversed-phase, cation-exchange, and anion-exchange as well as zwitterion-exchangeHPLC separation media. In short, a versatile omniphase has been created by these authors [256]. It is interesting to note that some chromatographers [257] have begun to experiment with HPLC column that are packed with a mixture of ion exchangeheversed phase or cation exchangelanion exchange media. It is clear that these mixed-bed columns will be useful; however much of synergistic effect of single-ligand multifunctional stationary phases
C
8
SiiO-Si-(CH2~-O-CH2-CH-CHZ
0
Scheme 7 Reactivesubstratesused for subsequentreactionsinthesynthesis zwitterionic stationary phases.A = propylamine bonded silica;B = glycidopropyltrimethoxy silica; C = l-dimethylchlorosilyl-2-m,p-chloromethylphenylethme silica.
109
Liquid Chromatography
+ - 0 - CH2-CH(0H)-CH2-N(CHd2-CH2
-Si
- CH2 - SO3b
2
\
0 -Si
-
(CH2)
a
C H82H- 2 -
2S(o-Si-(CH&-O-CH2-CH(OH)-CY-NH2-
coo H ; - CH3
+
C
CHz-COO-
d
e
Scheme 8 Structures of chiral and achiral zwitterion exchange phases:(a) achiral hydrophobic strongZSX phase; (b) achiral hydrophilic strongZSX phase; (c) chiral hyphobic weak WZX phase; (d) achiral hydrophilic weak WZX phase; (e) chiral hydrophilic weakWZX phase; (f) chiral glutamic acid phase.
such as the quadrupolar interaction between solute and ligands of bonded zwitterionic supports will be lost when such columns are made with mixed LC packing materials.
C. Alumina BasedPackings During recent years, numerous commercially available stationary phases based on silica have been improved in order to meet the general requirements for the chromatographic packings. However, and despite much effort, most of the available stationary phases have serious deficiencies in
110
Chapter
the chromatography of organic bases. Usually, peak tailing or irreversible adsorption prevents the analysis of such compounds. In this respect, aluminum oxide is an interesting base material because its chemical stability allows liquid chromatography with alkaline eluents. Thisopens up new possibilities,sincepeaktailingresulting from ionic interaction betweenthe charged basesand “active” centerson the surface of a sorbent can be overcome by using alkaline eluents. Due to its higher isoelectric point and higher stability in the alkaline pH range, alumina partiallyor totally overcomesthe difficulty arisingfrom the low pH stability of silica; therefore its application asa HPLC stationary phase for adsorption or (after modification) reversed phase chromatography offers considerable advantages [258]. The physicochemical characteristics of alumina have been reviewed [259].In Table 9 presentsthe commercially available alumina based HPLC packings. Cabrera et al. [260] introduce a new chromatographic support based on aluminium oxide, namely AluspherAl, manufactured by thermal dehydration of aluminum hydroxide. This material can be packed into HPLC columns with highseparation efficiencies comparableto silica columns. Aluspher A1 is, like silica,a typical sorbentfor normal phase chromatography. In this type of chromatographythe polarity of the phase plays a significant role. Afundamental advantage of Aluspher Al is its high chemical stability over a widerangeof pH (2-12).Moreover,itsamphoteric character makes it a sorbent with different chromatographic properties depending on the chemical nature of the eluent to be used. Aluspher Al in contact with alkaline eluents, for example, has different chromatographic properties than in contact with neutral ones. This can be explained by its chemical nature (Scheme 9). Coating of a hydrophobic polymer on Aluspher Al leads to a chromatographic material with typical reversed phase properties, namely, Aluspher-Select B. For example, Aluspher A1was coated with polybutadiene according to a procedure described by Figge [261]. Silica-based materialsare usually prepared by chemical reactionthe of silanol groups with alkyl silanes, leading to chemically stable stationary phases [262]. Silanization of aluminum oxide, on the contrary, does not lead to stable materials because ofthe lability of Al-0-Si bonds. Therefore, an alternative method for the preparation of aluminium oxide in the reversed phase modehad to be found, namely, coating with polymers. The separation of organic baseson silica-based reversed phase materials is usually very problematic. This is due to the presence of active sites, which complicate the retention mechanism and leads to peak tailing with polar solvents. In contrast to this behavior, Aluspher-Select B shows very
pplier
Liquid Chromatography
111
Table 9 Alumina Based Commercial Packings Pore Specific Particlesizesurfaceareadiameter Name Neutral alumina AG7 Basic Alumina AG10 Acid Alumina AG4 ICN Alumina N ICN Alumina A ICN AluminaB Aluminium oxide60 active basic Aluminium oxide90 active basic Aluminium oxide90 active neutral Aluminium oxide90 active sauer Aluminium oxide 150 basic Lichroprep Alox T Alox 600 Chroma Sep PAA HiEff MicropartAl
Micropack Al Pellumina HS ALU-H ALU-N ALU-OH
(nm)
-
Observations
Bio-Rad Bio-Rad Bio-Rad ICN ICN ICN Merck
18-63 18-32 18-32 63-200
pH pH pH pH pH pH pH
Merck
63-200
pH = 9
Merck
63-200
pH = 7.3
Merck
63-200
pH = 4
Merck
63-200
pH = 9.0
Merck
25-50
Basic alumina
Chrompack Tracor Applied Science Lab Varian Whatman Polymer Institute, Bratislava, Slovakia
= 6.9-7.1 = 10.0-10.5 = 3.5-4.5 = 7.5 = 4.5
= 10 =9
-
37-44 40-70 40-70 40-70
good chromatographic properties in the separation organic bases under neutral conditions. The objectives the studies inHPLC dealing withthe use alumina have been generally limited to the exploration of its separation capacity and did not investigate in detail the underlying separation and retention mechanism. According to ourknowledge, the retention mechanism and the
I12
Chapter
AI
I
t
Scheme 9 Chemical structureof aluminium oxide under “neutral” and “alkaline”
conditions.
separation characteristics of aluminaHPLC columns have never been studied in detail.
D. Polymeric ResinsBasedPackings Chromatographic columns containing polymeric resins have become increasingly popular because these columns have chemical stabilitythat cannot be achieved with silicaor alumina columns. Separation media basedon porous polymers are usually produced by suspension polymerization, and gradual improvements in reactor design and suspension polymerization methodology have allowed the production of smallerand smaller polymeric beads[263-2671. For example, the Hamilton Company (U.S.) introduced almost 15 years agoa spherical macroporous 10 pm styrene-divinylbenzene copolymer designated as PRP-l that is stable over apH range of 0-14 and that can be usedfor theseparation of a variety of organic molecules [268]. Other products were developed from this new material, such as PRP-X 100, a high capacity and high efficiency anion exchanger which is prepared from PRP-l by chemical modification [269]. Polymeric packings basedon methacrylate polymers have also been produced [2701. The most recent trend in the area of polymeric packings for liquid chromatographic columns has been to produce pellicular polymeric packings, which consists of thin layers of polymers chemically attached to the outer surface of small (3-5 pm), nonporous, spherical polymer beads.The short diffusion paths present inthe outer layer leadsto columns having very high efficiencies in additionto their inherent good chemical stability. Rollsetal.[271]introduced new polymer-based separation media containing phenolic functionalities of varying accessibilities. Polymeric res-
Liquid Chromatography
I13
ins containing phenol moieties were also chosen because their acidic hydrogenscan form strong hydrogen bonds withbasiccompoundssuchas amines, which are frequently difficult to separate effectively, and because this bonding, which mirrors that occurring between organic moleculesand the acidic silanol groupsof silica adsorbents, can be modified by changes in the steric environment. The reactions presented in Scheme shows the preparation of polymer-based separation media containing phenolic functionalities. In order to optimize the porosity and particle size of resins, in each experiment the monomer mixture consisted of50 wt% of commercial divinylbenzene (an almostequimolecularmixtureofmonomers 2 and Scheme 10) and 50 wt% of p-t-butoxy-carbonyloxystyrene.This monomer was chosen for two reasons: first, because the polymerization of unprotected vinyl phenols gives irregular and low molecular weights products which may be too soft forpractical use in liquid chromatographyand also
I
COOt-Bu
I
COOt-3~
R = H,CH3 or CH(CH&
Scheme Thepreparation of chromatographicpackingscontainingphenolic functionalities(R = H, CH,, or CH(CH,),).
114
Chapter
because the p-t-butoxy-carbonyloxystreneprotecting groups can be easily thermolyzed to yield the desired phenolic functionalities Each experiment was run at 8OoC for 16 h using an autoclave and AIBN as the initiator and a 2% solution of poly(viny1 alcohol) as the aqueous phase. Porosity was controlled by varying the amount and thermodynamic characteristics of the porogen used in the polymerization mixture, while particle size was controlled by changing the stirring speed and the relative ratio of the aqueous and organic phases. Table 10 lists the surface areas, solvent regain,and percent porosities of the polymers obtained in the various suspension copolymerizations using a variety of solvents as porogens. Table 10 Control of Surface Area and Pore Volume in the Copolymerization of p-t-Butoxy-carbonyloxystyreneand Divinylbenzene Porogen (volume Vo)
Surface area (m*g”)
l-Butylacetate(5OVo) 30 0.60 l-Butanol(50%) Benzyl1.33 alcohol(50Vo) Cyclohexanol(4OVo) 0.92 Cyclohexanol(5OVo) 1.64 Cyclohexanol(60%) 1.03 Heptane(5OVo) l-Butanol(30Vo) 0.43 l-Butanol(40Vo) 0.63 l-Butanol(50Vo) 1.36 l-Butanol(60%) 1.85 l-Butanol(7OVo) 1.75 l-Pentanol(60Vo) 1.91 l-Heptanol(60Vo) 1-Octanol(60Vo) 68 l-Decanol(60Vo)
1 4.8 71.0 1.o 34 190.0 227.0 197 1.o 11 1.3 4.8 143.0 26.0 145.0 136.0 93.O 66 44.0
Solvent regain (ml/g)
Porosity’ (VO)
0.43 0.52 72 0.12
1.95 2.10
‘Porosity represents the percentage porosity of each sample, which is calculated by the following equation: % Porosity =
100 v, v s + v,
where V , is the volume of cyclohexane taken up by 1 g of the polymer which can be determined from the solvent regain value. V, is the volume of 1 g of polymer beads. This volumeis taken as1.0 mL in each case because the density of this polymer matrix was determinedto be 1.0 g/ml from the value of its balanced density slurry. Source: Ref. 27 1 .
Liquid Chromatography
115
The theory of pore formation in macroporous resins has been reviewed in great detail by Guyotand Bartholine following earlier studies These studies, which involved mainlythe styrene-divinylbenzenesystem,showed that completelydifferentporousstructures are obtained depending on whether solvents or nonsolvents of polystyrene are used as porogens. Guyot and coworkers noted that styrene divinylbenzene resins are inhomogeneous because the divinyl components of this mixture (p- and m-divinylbenzene) are incorporated into the polymer resinmuchfaster than the monovinyl components (styrene, p - and methylbenzene). This gives rise to regions of high crosslink density, termed nodules, which are connectedby the lesshighlycrosslinkedmolecules formed at a later stage of the polymerization. Whenthe porogen isa solvent for the polymer molecule, such as toluene, the situation is very simple. If the amount of porogen istoo low, the distance betweenthe nodules will be very small and there will not be enough available volumefor the polymerization to proceed to completion without complete coalescence or overlap of the nodules. As a result, a gel-like resin withno measurable surfacearea or pore volume will be produced. When the amount ofporogenpasses a criticalthresholdvalue and the distancebetween the nodulesbecomes greater, because dilution effect, some empty space or small pores will remain betweenthe nodules at thecompletion ofthe polymerization, resulting in the production of a resin with a high surface area and a sharp pore size distribution. As the percentage of porogen is increased beyond this threshold value, the surface area and pore volume increase steadily. Because the porogen is a good solvent for the polymer molecule, there is no phase separation, and the result is a resin with a very uniform distribution of small pores When the porogen is a nonsolvent for the polymermolecule, the situation is much more complex. This applies to the system in which 1butanol is used as porogen because alcohols are poor solvents for styrene polymers. In the early stages of polymerization, the diluent mixture consists of the porogen and unreacted monomers. As the polymerization proceeds, the monomers are incorporated into the polymer and the composition of the diluent mixture shifts towards a higher percentage of the porogen, which is a nonsolventfor the polymer. When the percentage of porogen in the diluent mixture becomes large enough, a phase separation occurs, in which most of the porogen is excludedfrom the regions between the polymer molecules. Two phases are created, one containing a high concentration of polymer molecules, and the other containing mostly porogen. The volume occupied by the excluded porogen corresponds to the very large pores seenin the pore size distribution resins prepared using nonsolvents as porogens Comparative studies of various column packings
Chapter
116
wererealized [278-2931 in order to optimize experimental conditions of separations 1294-3 1 l]. Unexpected changes in separation efficiency are sometimes observed in liquid chromatography with columns filled with soft or semirigid organic supports. A detailed study of this phenomenon showed that is connected with changes in size of the swollen gel particles of the column packing. These changesare caused by the injection of solutes that reduce the swelling of the gel considerably or by accidental penetration of air into thegel bed [312].
E.
Carbon BasedPackings
Interest in carbonaceous packings as stationary phases in HPLC has recently increased because of the (theoretical) nonpolar character of these materials and the possibility of using them over a wide pH range. The principal problem isthe preparationof a suitable type of carbon thatwould meet the HPLC requirements, namely, mechanicalstrength of the particles, homogeneity, and asuitable specific surface area. The first attempt to prepare a carbonaceous packing suitable for HPLC was made by Guiochon and coworkers [3 13-3161, Bebris and coworkers [317,318], and Berek and coworkers [319-3221. The most important advantages that can be expected from carbon packings in comparison with silica gels or alkyl-bonded silica gels include their high chemical resistance to various mobile phasesand their high chemical resistanceto various mobile phases and their total inertness toward separated substances. The expectation of chemical resistanceis fulfilled. On the other hand both the porous glassy carbon and the porous graphitic carbon turned out tobe very strong adsorbents and this property has to be moderated by a properly chosen mobile phase composition by polymer coating or by a chemical modification of the surface. The rate of mass transfer within carbon-based packings is somewhat lowerthan within silica gels.This indicates the necessity of improving the texture of particles, e.g., by generating a spongelike structure andby removing the micropores and all irregularities arising during preparation of the sorbent matrix. Using quantitative structure-retention relationships as a tool fordiagnosing retention mechanism of the carbon-based packings,Bassler and Hartwick [323] have demonstrated the role of the ?r electronic structure of graphite in the retention of solutes. The graphite surface is sensitive to changes in the solute electron density caused bythe electron donating and withdrawing ability of solute substituents and the number and position of electron-dense ?r bonds in the solute. Furthermore, porous graphitic carbon is highly sensitive to steric changes that disturb the electron density of the
Liquid Chromatography
117
solute molecule and the resulting interaction ofthe solute withthe graphite surface. a result, porous graphitic carbon is uniquely selectiveto positional and stereo isomers. Meso- and macroporous mechanically stable, noncomposite carbon packings can be prepared in several ways: Calcination of cokes followed by extraction leading to packings with variouspore sizes [3241. Electrochemical reduction of polytetrafluoroethylene with lithium amalgam at room temperature [325]. The resulting angular materials with small pore volume but with very high specific surface area, contain many micropores. The template (replica) method where the pores of the appropriated silica gel are filled with a carbon precursor, e.g., with phenol-formaldehyde resin [326]; the carbon precursor is carbonized at temperatures of 650-1000°C, and finally the silica gel is leachedout under alkaline conditions. The controlled pyrolysis ofthe polymeric carbon precursor particles impregnated with porogenes [320]. The porogenes can be either active, attackingthe precursor matrix or inert, solely supporting the evolving carbon structure or a mixture ofboth. After pyrolysis ofthe precursor matrix, the porogenes are washed out. The phase separation of a liquid carbon-precursor and a liquid auxilliary compound followed by the solidification of the system, pyrolysis of the carbon precursor, and finally by washing out the auxilliary compound[3191. The porous carbon particles can be prepared in spherical form provided the starting silica gel templates (process 3) or the starting carbon precursor particles (process 4) are of spherical shape or, finally, the phase separation and solidification proceeds in microdroplets dispersed inan appropriate (e.g., polymeric) dispersing medium (process 5) [327]. The size ofthe pores in the resulting carbon packings is determined by the structure of the silica gel template (process 3), by the type of carbon precursor, as well as by the porogene used. The chemical structure of the materials obtained by carbonization is rather complicated since they contain many polar groups [328]. The polar groups, but also the micropores, can be removed by appropriate thermal treatments under hydrogen, i.e., in the course of so-called deactivation at 100O-12OO0C during production of glassycarbon, at 1500-200O0C, or during transformation to the graphite carbon above 200OoC. The primary material obtained by carbonization can be readily modified by a surface grafting of the monomeric or polymeric groups.We believethat chemically .
..
Chapter
118
modifiedmacroporouspyrolytic carbon packingscouldachievegood HPLC properties that demanding graphitization may be avoided. The review by Knox and Kaur [ also covers application of porous graphitic carbon and draws attention to several interesting properties of this material. The nonmodified macroporous graphitic carbon can be used for purification and preconcentration of samples before their analyses.Porous carbon-based packings are generally the HPLC column packings of the future but material with better pore structure yielding higher chromatographic efficiency must be developed. Research on HPLC column packings is nowadays very intensive. It concentrates on the problemsassociatedwithsurfacemodificationof known matrices, especially silica gels. We believe that several other problems should also be solved,for example: The synthesis of nearly monodispersed spherical silica gels of different mean particle sizesas well as different meanpore sizes and pore size distribution,preferablywith a sponge-likeporous structure and with largepore volume combined with good mechanical stability. Continuous production of silica gelsand other packings at lower cost and with improved repeatibility of their properties. The synthesis of composite packings in which the pores with mechanically stable matrices are filled witha network soft, slightly crosslinked macromolecules. The synthesis of packings with improved mass transfer as such pellicular materials with a thick porous layer, crazed materials, etc. The preparation of homogeneous and stable beds of packings which have reduced interstitial volume. In addition to the conventional packingsmade from silicondioxide and organicpolymers, new types of matrix building materials such as carbon and nonoxide ceramics deserve increasedattention.
COLUMN PERFORMANCES Resolution,Selectivity, and Efficiency
The goal of chromatography is to separate components of a sample within a reasonable period of time into separate bands or peaks as they migrate through a column. When two kinds of solutes are in a chromatographic system, the resolution, Rs, is defined as the retention volume (or time) dividedby the mean peak width The precise definition now recommended by the International Union of Pure and Applied Chemistry is:
119
Liquid Chromatography
Rs =
v2 -
VI
< W>
where V . and V, are eltItion volumes ofthe retained components measured at the peak maximum and < W > is the average peak (base) width determined from tangents to the peak curves at their points of inflection (see Fig. 9). If one represents the peaks schematically as two isoscele triangles, then Rs as defined above gives exactly 1 for nonoverlapping triangles in contact as shown in the exampleinFig. 9. The Rs equation is usually expressed in terms of more common chromatographic parameters: the column efficiency, the average capacity factor < k > = 1/2(kl k2),and the selectivity ratio a = k2/kl.
+
-1 Rs = 2 l + < k > a + l
where n represents the number of theoretical plates. It is often stated that a resolution Rs = 1 corresponds to about impurity or to 98% purity in a peak. One should keepin mind, however, that the validity of these benchmark percentages depends both on the relative concentrations of the two solutes and on the relative detection efficiencies with whichthe chromatograms are recorded.
200
400
Figure 9 The definition of chromatographic resolution.
120
Chapter
Figure 10 Resolutionandefficiencyversusselectivity: a, sampleinjection; A, poor resolution;B, good resolutiondue to the column efficiency;C, good resolution due to column selectivity.
Fig. 10 illustrates that the value of the resolution depends upon two factors: narrowness ofthe peak and the distance betweenthe peak maxima. The resolution is also influenced by the length of the chromatographic column. A later section will show how the column length can be increased in order to increase the value ofthe resolution. In practice, it is seldom necessary to calculate the value of the resolution. More frequently, the chromatographer simply looks at the shape of the peaks and estimates the R, value from peak shape. From inspection of the peak shapes one can generally estimate the resolution to a sufficient degree to quickly selectthe length of column requiredfor theseparation.
Liquid Chromatography
121
Generally, improving column efficiency by decreasing the width of the band is the most desirable way of improving resolution since it saves time. Column efficiency aisfunction of column parameters, such as solvent flow rate, the particle size of the column packing, the method packing the column, and the viscosity of the solvent. It is also possible to improve the resolution by changing the column selectivity, but if the efficiency is constant, increasing the resolution usually involves longer elution times for a particular system. For example, column selectivity is governed by thermodynamics of the interaction the solute with the solvent and the column packing. Column efficiency can be measured quantitatively by the following equation 2
N=(:)
t
t
W
W1n
=16--5.5-
(75)
where W is the peak width at the baseline, w , , the ~ width at 'h peak high, t retention time, peak standard deviation, and N the number of theoretical plates. shown in Fig. 11 the value of N can be measured by taking the quotient of retention time divided by peak standard deviation or the peak width at 'h height or the peak width determined by extrapolation of the tangents to the peak to the baseline, W . Since the objective of chromatography is to separate species by their molecular structure (or molecular weight as in the case of oligomers and polymers), it is desirable to have some means of describing howwell a column will do this job.
\
/
\
Figure 11 Calculation of theoretical plates.
122
Chapter 3
A chromatographic separation process can be consideredto occur in
a series of hypothetical steps, within each of which equilibrium is achieved between solute concentration in the mobile and stationary phases. Each steps is termeda plate and is considered to correspond to a specific height of the column. The concept of a theoretical plate was developed in 1941 by Martin and Synge in their Nobel Prize winning paper [336]. The plate height concept was a direct result of the theory. But it does not relate particle size, diffusion, flow rate, temperature, and solvent viscosity to the performance of the column. Later, the rate theory was developed by Giddings [337] in 1955 and extended by Van Deemterin 1956 [338]. When a monodisperse substance is passed through a chromatographic column, it is eluted with a distribution of retention times. The detailed mechanisms responsiblefor this phenomenon are complex and varied in nature that they are notwell understood. The theoretical plate concept does not imply,however, that the dispersion occurs in the macroscopic and microscopicscaleduring the passage of individualmolecules through packed column. Rather, the theoretical interpretation of chromatographic separations are mathematical models of an idealized physical process that allow usto predict separation and broadening behavior. As pointed out by Cazes [339] the theoretical plate concept is borrowed from that area of chemical engineering involving fractional distillation. A theoretical plate, in the case of distillation, refers to a discrete equilibrium stage constituting a simple distillation in which complete equilibrium is established between the two phases. In chromatography where the mobilephaseisin constant motion,equilibriumisprobablynever achieved. The true semnification of the theoretical plate is lost. It must be realized,moreover, that the calculatedtheoreticalplatein a chromatographic column represents smaller separating ability than the theoretical plate in a distillation column by a factor of twenty-five to fifty. Table l1 compares the number of peaks resolvable at various theoretical plate levels. Although the actual separation in chromatography does not occur in true equilibrium conditions, the concept of a theoretical plate has provedto be extremely usefulfor characterizing column efficiency. Quite often plate count, which is the number of theoretical plates per foot,
with LC = total column length in feet, or its reciprocal, the “height equivalent to a theoretical plate:”
123
Liquid Chromatography
Table 11 ComparativePeakCapacity of Various Chromatographic Methodsfor Given Numbers Theoretical Plates
n NGC
GPC
100 400 1 512,500 101 10,000
3 5 7 11 21
11 21 33
7 13 20
GPC = gel permeation chromatography or size exclusion chromatography; GC = gaschromatography; LC = liquid chromatography. Source: Ref. 340.
(-)
1 L, W H ==PC 16 t
2
(77)
are used since these equationstake into account the total column length. Eqs. 76 and 77 are more a measure of how well a column is packed, that is, how much peak spreading it will cause, than how wellit will resolve. Because of the mathematical nature of the plate height definitions, most of the theoretical expressions developed to predict broadening have utilized this concept.In general, the height equivalentto a theoretical plate, H , is predicted in terms of operating variables. The height equivalent of a theoretical plate is the preferred measure of column efficiency because it allows a comparison between columns of different lengths. Phenomenasuch as eddydiffusion,moleculardiffusion,velocityprofile effect (or nonequilibrium effects) inthe mobile phase, dead-volume effects, sorptive effects, viscosity effects (such as viscous fingering), and dispersion due to diffusion into and out of the pores (the permeation process) may be encountered to varying degrees in chromatographic separations. Broadening can be further separated into mobile-phase dispersion occurring inthe absence of permeation or adsorption, and broadening associated with the separation mass-transfer process itself. It is important to understand the dispersion contributions occurring in the mobile phase (in the absence of mass transfer) before attempting to interpret the overall dispersion present in actual chromatographic systems.
Chapter
124
In general, plate height H may be related with dispersion by the following equation:
H = - + a mass transfer contribution U
(78)
where D is an overalldispersionnumber.Utilizingthis equation, Van Deepter [338] assumed that the dispersion number was composed of a longitudinal molecular-diffusion termand aneddy-diffusion term, and that the mass transfer equation was a linear function of eluent velocity: molecular diffusion
eddy diffusion
(79)
where 4 is a tortuosity factor ( 4 = 2 / 3 ) and is an eddy diffusion proportionality factor 1/11). This resulted inan overall equation for a plate height of the general form
H =A
+
(B/U)
+ CU
(80)
where the first term accountsfor eddy diffusion, the second termfor molecular diffusion, and the third term for mass-transfer resistances in the stationary and mobile phases. In the absence of mass transfer processes, and with appropriate substitutions, eq. 80 becomes:
+
H = 2Xdp (81) 24Dm/U that applies to mobile phase dispersion effects. For some chromatographic systems, Van Deemter’s approach did not correlate well with experimental results [341].Perhaps the most important reason for lack of correlation was the difficulty in accounting adequately for the complex velocity and plan profiles existing within packed column. The concept of eddy diffusion is highly idealized and assumes that packing particles are uniform. Further objections arose in the form of the masstransfer contribution to plate height. It was to explain these deviations between theory and experiments that Giddings [342,343] stated his “coupling theory.” In this theory, the eddy diffusion is coupled in a nonadditive manner with the mobile-phase resistance to nonequilibrium mass transfer. In general form, the coupling equation theory of Giddings may be written
where U is eluent velocity, B takes into account molecular diffusion, C, accounts for mass-transfer effects in the stationary phase, Ai accounts for eddydiffusion, and Cmitakes into accountmass-transfereffectsin the
Liquid Chromatography
125
mobile phase. For describing mobile phase dispersion in the absence of mass transfer between a stationary and a mobile phase, Giddings coupling theory predicts
c
2rDm H=-+
U
i
1
( 1/2Xpp)
+ (Dm/wp;U)
where S, hi, and wi are geometrical constants. In termsof the reduced parameters h and v, eq. 83 becomes h=-+ V
c (1/2Xi) +1 i
( ~/w,v)
where H h=-andv=dP
Ud Dm
Another approach [344-3461 which helps to explain the origin of coupling has been to extend Van Deempter’s theory by incorporating an additional term to account for velocity profile effects caused by a nonuniform velocity over the column cross section. nonuniform A velocity profile causes a spread in retention times whose magnitude is determined primarily by radial (transverse) diffusion.Sie and Rijnders [347] found this approach valuable for describing band broadening in packed chromatographic columns for gaseous systems, and pointed out thatit may alsobe useful in liquid chromatography. Most chromatographic columnpackingmaterialshavearelatively wide particle-size range. During column packing, the particle can segregate, producing some cross sections having a small-particle-diameter packingand other having large-diameter packing. Such particle size segregation, coupled with variations in packing density, presents variable resistance to the flowing fluid and leads to a nonuniform velocity profile. Because the column void fraction is greater nearthe wall, the flowing fluid encountersless resistance there, and the average velocity near the wall is correspondingly greater than thecenter of the bed [ 348-3501. The overall longitudinal-dispersion numberD is therefore assumed to be the sum of contribution from molecular diffusion, eddy-diffusion and velocity-profile effectsoperating in the column:
D = +Dm + XUdp eddy molecular diffusion
+
HRlU’ D,
diffusion
ve’ocity profile effects
Chapter
126
where is a velocity-profile constant, R, is the column radius, and Er is an average radial diffusivity. This form of the expression for the overall dispersion number was developed by Taylor and Aris [35 1-3541. In cases where a mass-transfer process such as adsorption or permeation is absentor negligible, the plate-height equation becomes
in actual The utility of this equation for describing mobile phase dispersion liquid chromatographic systems depends greatly on the evaluation of the average radial diffusivityDryand the appropriate velocity-profile constant II for the experimental column used. Experimental results have shown that radial diffusivity is determined by the radial gradient within the column that comes about from both molecular diffusion and eddy-diffusion processes [355].
where is a dimensionless radial position variable: = r/R,
where r is the actual radial position variable. From eq. radial diffusivity is
87, the average
The biggest drawbackfor utilizing the velocity-profile model in the past has been the difficulty in evaluating the velocity-profile constant Johnson [356] has rigorously evaluated A for packed-bed systems as a function of aspect 6 and (which is a measure of the relative importance of eddy diffusion versus the combination of eddy and molecular diffusion) [356], given bythe following relation: Ud, XUd, +Dm
+
As a result, it is now possible to determine graphically the velocity-profile constant representing6 versus 116 [3461. Incorporating these concepts, the plate height equation describing mobile-phase dispersion witha velocity-model becomes
Liquid Chromatography
I27
Huber [357] has developed a theory to describe broadening in liquid chromatographic systems. The overall expressionfor plate height is expressedas a sum of individual contributions that include mixingarising from diffusion in the mobile phase ( H m d )mixing , due to convection in the mobile phase (H,,,,), and the stationary phases (H,). These effects were assumed to be independent and additive quantities such that
H =
+ H,, + Hem+ H ,
(911
where
Ha =
1 E, -
(E,,
E , + K~EB E,,,( 1 - E,)T, diu + Kie8I2 Ea DiS
where = the theoretical volume fraction = theinternal pore volume fraction occupiedby stationary fluid E,, = volume fraction occupiedbymovingphase 7s = volume fraction occupiedby stationary phase X1, X, = geometric constants r,, rs = tortuosity factors Ki = distribution coefficient equal to the ratio of the equilibrium concentrations in the stationary and mobile phases Tu = the kinematicviscosity of the mobilephase = the diffusion coefficient in the mobile phase D* = the diffusion coefficient in the stationary phase Em E,
Huber’s approach takes into account the specific volumefractions in which the broadening processes are occurring. The overall plate curve as a function of fluid velocity is concave downward with decreasing flow rate until molecular diffusion effects beginto dominate where a sharprise in H is observed. The effect of Hmdis lessimportant athigh flow rates.Contributions due to Hemand H,, are both concave downward with decreasing flow rate, with largercontribution coming from H,,,,. The term H , is linear with flow rate. The overall plate height behavioris quantitatively very similar to that of Giddings [344]and Kalley and Billmeyer [346,358].
Chapter
128
Broadening occurring in the mobile phase results by definition from all dispersion processes that affect the residence time distribution but in which the solute molecules are not removed from the mobile phase. Adsorption and permeation are mass transfer processes which involve a stationary phase in whichthe solute molecules becometemporarily entrapped during their passage through the column. Major sources of mobile phase dispersion included in the theoretical models just discussed are molecular diffusion, eddy diffusion, andnonequilibrum effects associated with velocity variations due topacking geometry, Dispersion associated wtih stagnant regions, boundary-layer phenomena, natural convection effects resulting from density gradient, viscous fingering and other concentration effects have not been incorporated into themathematical dispersion models.All of these effects could be presentto varying degreesin an actual column system and would lead to disagreement between theory and data. It is probably that stagnant regions or “deadvolume” areas do exist in real systems. Transfer into and out of such dead volume is diffusion controlled and would givea linear contribution to plate height. The above treatments of chromatography werebased on a model consisting of a large number of theoretical plates, in each of which local equilibrium betweenthe two phaseswas assumed. Suchtreatments consider the chromatographic process to be a multistage distillative process. In chromatography the moving substance is distributed between a “free” and “bound” state Distribution may result from the presence a support towhich the substance is retained. In all the cases the partition process is assumed to be quasilinear, which means that the concentrationsf and b in the free and bond state respectively are given by
and the following expression governsthe transport of matter under influence of flowin the unidimensional case:
(5)
=
where is velocityof the substance, c is the concentration and is a function of and t , and D is a diffusion constant; I, and l, are the mass transfer coefficients. In chromatographic columns the support itself participates in the partition process. In these heterogeneous processesthe assumption of linearity is only approximately fulfilled. This can only lead to results more or less correct depending on the geometry of the system. Furthermore, the equa-
Liquid Chromatography
129
tions do not include the statistical variations of the transport velocities caused by the grain structure of the support. Thus the exact solutions of eqs. 96 and 97 are of limited value asthe equations themselves are open to criticism. Moreover, they offer more information than required for practice. The chromatographer is interested in quantity, displacement, width, and skewness of the mass distribution (f + b ) and the intention is to deduce these variablesfrom the measured signals. These signals are obtained either as a function of time (liquid chromatography) or as a function of place (thin layer chromatography). There is a relation between the above mentioned variablesand the moments of the signals which are defined as a partial integral
M. =
1
t'S,,,dt
(99)
where tis either timeor a coordinatedepending on the experimental conditions. These moments are a preferably linear function of the respective identically defined moments the of concentration distribution and are calculated from theformulas. In these moments eachterm is physicallyclear.
IV. CHOICE AND OPTIMIZATION OF VARIABLES IN LIQUID CHROMATOGRAPHY A. SolventSelection For many years, the study of high-performance liquid chromatography selectivity and structure-retention relationships has been complicated by the large number of liquids available for use as mobile phase solvents. These solvents possess sucha great diversity of polarity and selectivity that capacity factors ( k ' ) can be varied by a factor of l o 3 simply by changing the composition ofthe mobile phase[360]. The polar adsorbents behave as though it has active sitesthat provide retention of the solutes. In fact, these active sites appear to have varying degrees of strength [361]. Adsorption of the strongest of these active sites can lead to the phenomena of extremely long retention times and/or peak tailing. In somecasesirreversible adsorption at the strongest sites may result. To reduce the effect of strong interactions, the adsorbent activity is usually controlled or modified witha fixed wateror alcohol content. The adsorbent water content of these packingsthat can be dry-packed is usually adjusted prior to preparation of the column. Experimentally this is usually done by heating the packing for 4-6 hours to remove the residual water. For silica materials the temperature should be in the 125-150°C range, while for alumina a rangeof 125-250°C isnecessary. A known amount of water is then added and the material is mixed in a closed con-
130
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tainer until all the lumps have disappeared. Strong agitation, such as laboratory shakers, should be avoided since this treatment tends to fracture the packing. It has been experimentally determined that for silica gel a water content of 0.02-0.04 g per 100 m2 of surface area gives maximum linear capacity [3611. For a microporous adsorbent, such as LiChrosorbTM, this would be about 8-12 by weight. For a pellicular adsorbent with a lower surface area, only 0.5-1.59’0 weight is required. Materials in the 5-10 pm region, now very popular in liquid chromatography, are generally packed by slurry techniques.The level of adsorbed water on these materials is generallyadjusted after preparation of the column by modification of the mobile phase since slurry solvents would undoubtedly affect the water content of the adsorbent if deactivated prior to packing. In theliquid chromatography separations,the mobile phaseis in competition withthe solute for the active sites. This equilibrium is controlled by the mass action law.Thus, if we adjusted the water content of our column and then began pumping a “dry” solvent through it, we would expect that eventually the dry solvent would remove the watermolecules from the surface and increase the activity of the column, i.e., the retention timesand peak tailing would increase. Conversely, if the mobile phase were “wet,”we would expect deactivation of the column and decreased retention times. Thus, it is veryimportant to maintain a constant water or modifier level on the solvent [360]. Only when complete thermodynamic equilibrium exists between the mobile phaseand the deactivated adsorbent will retention times be reproducible. Remembering that the solvent and solute are in competition for the active sites ofthe adsorbent, it is easy to deduce that the more stronglythe mobile phase interacts with the adsorbent the quicker the solute will elute from the column. Thus, the major factor determining retention in liquid chromatography isthe relative polarities ofthe mobile phaseand the solute. A polarity scale can be established by empirically rating solvents in order of their strengths of adsorption on an adsorbent, such as silica. A solvent higher in polarity will displace one lower in the polarity scale. Sucha scale is called an eleutropic series. Such a series developed for alumina (and approximate for silica) is shown in Table 12. Selection ofthe correct mobile phase strength is generally a matter of trial and error. Often thin layer chromatography or open-column data can be utilizedas a reasonable starting point. If no clue is available as to the proper solvent strength to be used, a good starting solvent is a 50/50 (v/v) mixture of hexane and methylene chloride modified with 0.1Vo isopropanol. Depending upon the chromatogram obtained using this solvent, the retention may be increased (or de-
Liquid Chromatography
I31
Table 12 Eleutropic Series for Alumina
Solvent
EOa
n-Pentane Isooctane Cyclohexane Carbon tetrachloride Xylene Toluene Benzene Ethyl ether Chloroform Methylene chloride Tetrahydrofuran Acetone Ethyl acetate Aniline Acetonitrile i-Propanol Ethanol Methanol
0.00 0.01 0.04 0.18 0.26 0.29 0.32 0.38 0.40 0.42 0.45 0.56 0.58 0.62 0.65 0.82 0.88 0.95
Acetic acid
large
“The called the “solvent strength parameter,” is a quantitative representationof solvent strength. Source: Ref. 361.
creased) by appropriate changes in the hexane-to-methylene chlorideratio. Increasing the methylene chloride content will serve to decrease retention time. Another widely accepted techniquefor characterizing solvent selectivity is the solvent selectivity triangle concept that establishes the primaryselectivitycharacteristicsofvarioussolventsaccording to their relative ability to engage in proton acceptor, proton donor, and strong dipolar interactions. When the resulting values are plotted on three axes in the form of a triangle, solvents having similar functionalities tend to fall within the same area of triangular plot.The theory of the solvent selectivity triangle concept isthat solvent groupedin the same area of the triangle will have similar selectivity, while solvents from the other groups should exhibit different selectivity for a given separation. This theory has been widely accepted and has often formed the rationale for solvent selectionfor a given separation, optimization technique,or structure-retention study
I32
Chapter
Until recently, definitive studies on the accuracy of this approach have been lackingand two publications [370,371] have questionedthe reliability of the selectivity triangle for grouping HPLC solvents according to their resolving abilities. The solvent triangle has not accurately predicted normal phase (NP) or revered phase (RP) selectivity for the separation of polystyrene oligomers [370]or RP selectivity for the separation of steroids 13711. The study with polystyrene oligomers showed that the degree of solute solubility in the pure mobile phasewas a better predictor of selectivity than were the groupings of the solvent triangle, while the study with steroids demonstrated that RP-HPLC retention indices based upon 2-keto alkanes can beused to accurately predict and optimize resolution with isocratic or gradient elution. The failure of the solvent selectivity triangle concept with polystyrene oligomers and steroids both occurred with the separation of compounds possessing similarfunctionalities. The data from previous studies [370,371] published in this area suggests that each of the HPLCsolvents studied offers some unique selectivity that cannot be duplicated by any of the other solvents. Consequently, proposals that utilize onlya few preferred solvents for optimization of separations in HPLC can result in overlooking many common solvents that exhibit the required selectivityfor agiven separation. The selectivity triangle concept fails to group HPLC solvents and liquid chromatographic stationary phases accordingto selectivity for resolving compound mixtures. The concept fails because the triangle is constructed from data that are notonly unrelated to experimental resolution, but which also mask solvent differencesby expressing solubility as normalized functions of summed retentions rather than as absolute differences in retention. Selectivity can be correlated with HPLC retention indices in a manner such that experimental resolution can be predicted accurately. By adjusting retention indices obtained with the various solvents for differences in slopes of the 2-keto alkanes retention index calibration line, it is possibleto characterize RP-HPLC solvents in a manner that directly reflects selectivity differences [372,373]. The interactive or retentive mode of liquid chromatography or high performance liquid chromatography of copolymers and cooligomers are based on the differences in the interactions between the column packing, mobile phase, and macromolecules of different composition. This leads to defined inequalities in adsorption, absorption (partition),ionic or precipitation-redissolution processes and, consequently, to the differences in the retention volumes of particular species. The size exclusionchromatography or gel permeation chromatography mode separates macromolecules according to their size in solution. This is governedby both the molarmass
Liquid Chromatography
133
and the chemical composition of the macromolecule. The adsorption and precipitation modes, that is, high performance liquid adsorption chromatography (HPLAC) and the high performance liquid precipitation chromatography (HPLPC) is in fact a combination of precipitation and sorption and not a classical precipitation and are the interactive liquid chromatography procedures most popular for the separation of macromolecules. To facilitate the control of the interactions in HPLAC and HPLPC systems, mixed mobile phasescontaining two or more components are used. For retention control in HPLAC eluent, additives withhigh elution strength, that is with high desorption ability, are used. In HPLPC the precipitation-redissolution processes are governed by addition of appropriate nonsolvents to the eluent. Most separations in the retentive liquid chromatography of macromolecules are performed with a gradient elution, when the composition of eluent is changed in either a continuous or stepwise manner according to a precise program, with the column temperature being kept constant. The conditions of HPLAC are chosen in such a way that the separation is not influenced by the molar mass of the macromolecules and the chromatogram represents onlythe chemical composition distribution of the sample. That is, the mobile phase composition, temperature and column packing, nonporous, microporous, or megaporous are selected that no size exclusion phenomena takes place within the liquid chromatography columns. The fractions obtained may be further separated according to their molecular weight by means of gelpermeation chromatography. The interactive liquid chromatographic separations are usually performed in the conventional elution mode in which the narrow zone of the sample is injected onto the column packing and subsequently eluted by pumping mobile phase through the column. In the HPLAC method the stepwise elution of copolymersis also possible. Here the column packingis saturated by the adsorbed copolymer that is eluted in the following steps by appropriate mobile phase(s). The necessity of changing eluentcomposition in both HPLAC andHPLPC methods presentsan importantdisadvantage. The controlled interaction the oligomer end-groups with column packing has been shownto lead to the increased selectivity ofseparation as was manifested for polyethylene glycols and polypropylene glycols With the increased molecular weight ofthe sample, however, the influence the end-groups is insufficient and theinteraction of main chain withthe column packing mustbe utilized. For this purpose, two- or multicomponent eluents are again advantageous since they allow preciseadjustments of the elution strength in connection with the nonswelling, mechanically stable, active column packings such as silica gelor porous carbon. An interesting phenomena was observed by Belenkii and Gankina
134
Chapter
[379] by varyingthe eluent composition in a mixture of thermodynamically good solvents. The experiments involvedthe gel permeation chromatography of polystyrene on silica gel in a thin layer chromatography arrangement. They arrived at a system in which the retention volumes were independent of the molar mass of the polymer. In fact the R, values of the polymers were as high as the R,s of the inert low molecular weight substances. Belenkii and Gankina [379] called these conditions “critical.” Under critical conditions the macromolecules are “invisible”to the gel. In this way the gel seems to be totally permeable, independent of its pore size. Tennikov has found a similar effect in a column liquid chromatographic arrangement [380] Nefedov and Zhmakina [381] haveadded that the critical composition of an eluent, for a given polymer and sorbent, may also depend on the pressure withinthe system. Belenkii and Gankina [379] proposed that at the critical eluent composition the total free energy ofthe process whichtakes place inthe column is zerodue to abalancing ofentropic (exclusion) and energetic (adsorption) effects. This is somewhat unexpected sinceboth the entropic and enthalpic terms change withthe molecular weight of the polymer. To achieve a retention independent of exclusion therefore requires the two effects to have an identical molecular weight dependence. Such a case would certainly not be expected a priori; however, the elucidation of critical conditions iswell documented in several polymer-binary eluent-sorbent systems, for oligomersand polymers upto 100,OOO daltons (Table 13). This includes the separation of cyclic oligomers [382].The latterindicates that critical conditions can possibly separate not only according to composition and molecular weight but also by spatial structure. On the other hand,Berek and coworkers [322,394-3971 extend molecular weight range to above one million daltons andpropose the term “limiting condition” instead of critical condition to avoid confusion with supercritical fluid chromatography that is based on an entirely different premise. In addition, Berek [394] found a new approach for thegeneration of limiting conditions. The eluent is a de facto nonsolvent for the sample (mixture of good and poor solvents) with the polymer injected in a thermodynamicallygoodsolvent. The adsorption, and possibly also precipitation, are controlled by the thermodynamic quality of the eluent. This differs from the critical conditions approach of Belenkii and Gankina [379] where the elution strength of the eluent controls the adsorption. In the system proposed by Berek [3221 there are still several unanswered questions in connection with the truemechanism that acts during the separation process. The primary differences between the Berek system and the approach of Belenkiiare
135
Liquid Chromatography
The use of a nonsolvent as eluent The injectionof the polymer in a thermodynamically good solvent discussed above, the separation of polymers under limiting conditions has some specific features.For example it enables one to exclude or at least to minimize the influence of different molar masses of macromolecules on theliquid chromatographic separation that other properties of both their structure and composition play a decisive role in theseparation. At present a precise and reproducible method doesnot exist for theseparation of copolymers or co-oligomers according to molecular weight. Since the behavior of macromolecules under limiting conditions seemsto be exTable 13 Critical Conditions for Systems of Polymer-Sorbent-Eluent
(composition, Polymer Eluent Sorbent vol. Polystyrene Oligobutadiene
Oligosulfone Oligocarbonate Oligo(buty1ene terephthalate) Oligo(propy1ene glycol) Oligo(ethy1ene glycol)
Oligo(diethy1ene glycol adipate) Oligo(methy1methacrylate) Oligo(buty1 methacrylate) Oligo( 1,3,64rioxocanes) "SI = silica gel. bMBK = methyl ethyl ketone.
T H F = tetrahydrofuran.
07'0)
Chloroform/tetrachloromethane, 94.V5.5 SI-100 HexaneAoluene, 85/15 Hexane/dichloromethane, 76/24 Heptane/MEKb,99.Y0.5 SI-60 Chloroform/ tetrachloromethane,53/47 SI-60 Chloroform/ tetrachloromethane,30/70 SI-60 THFc/heptane,80/20
SIa
MEK/ethyl acetate, 5/95 MEK/chloroform, 35/65 MEK/hexane, 92/8 THF/ethyl acetate,7/93 MEK/ethyl acetate,27/73 SI-100 Hexane/MEK, 8/92
SI-60 SI
SI-300 Dichloromethane/acetonitrile, 41358.5 SI-300 Dichloromethane/acetonitrile, 90.7/9.3 SI-C,, Acetonitrile/water,49.W50.5
Ref.
Chapter3
136
traordinarily sensitive to small changes in the eluent composition, temperature, and pressure, this approach seems very attractive for the differentiation of macromolecules. Another advantage of the separation under limiting conditions is that the separation proceeds isocratically. This excludes the problems connected with gradient elution (re-equilibrating columns by long-term washing, non-suitability of some detectors, baseline instability) that render gradient procedures less sensitivethan high performance liquid chromatographic methods. Future research will focuson a comparison of the limiting conditions generated by varying the thermodynamic qualityand solvent strength ofthe mobile phase. This will include solvent-solvent, solvent-poor-solvent and solvent-nonsolventsystemswith both polar and nonpolar constituents. Other additional questions which remainto be answered include the influence ofthe pore diameter, surface compositionand preferential sorbtion of the silica gel, the adjustment of limiting conditions by variation in the temperature and the effect of the injected polymer concentration on the retention volume.The latter may bean important advantage ofthe thermodynamic quality approach since for eluents containing a combination of solvents and nonsolvents near the &point the retention volume is independent of the concentration of the injected polymer. However, concentration dependent retention volumes have been identified for binary eluent combinations of two thermodynamically good solvents far from the &composition. Another question isthe generalization of limiting conditions by correlating the shifts in calibrationcurvescausedbyeluentcomposition changes with macromolecular properties such as size, preferential solvation, and solubility.
B. Influence of the Pressure Upon the Column Performances
The pressure generated bythe resistance of the column to liquid flow isan important and highly useful operating parameter in high pressure liquid chromatography.Manycolumnparametersinfluence the pressure. The pressure drop AP is given by
where r] = fluid viscosity, L = column length, v = flow velocity, dp = particle diameter, and 8 = dimensionless structural constant of order 600 for packed beds. Thisequation shows that small particles give higher pressure drops. The pressure drop can be minimized by using solvents with low viscosity.
Liquid Chromatography
137
Pressure influence upon liquid chromatographic separation was important in the case of the application of the recycle techcnique. Recycle liquid chromatography is a special technique of column programming for improving resolution by passing the sample through the column, or set of columns, repeatedly. Yet, recycle liquid chromatography represents an efficient way of exceeding the intrinsic limits of liquid chromatography and also of solving new details of the composition of natural or synthetic oligomers. In practice,recycleislimited,however, to separation of the mixture into a very few compounds, with very similar chromatographic behavior. Originally, recycle chromatography was performed by passing the effluent from thedetector backthrough the inlet ofa reciprocating high pressure pump and then on the column again. Although recycle has received much attention in the commercial literature, its real utility seems limited. Moreover, pronounced baseline perturbations were repeatedly observed in liquid chromatography both in alternating recycling and in backflushing experiments when binary eluents and refractometric detectors were used. The perturbations, which are called “eigenzones,” appeared immediately after operating the recycling or the backflushing valve, and their size and shape depended on the nature of both the column filling and the mixed mobile phase aswell as on the pressure drop across the column. Experimental results presented confirm that the primary causes of the eigenzones were the pressure changes in the columns which influenced the sorption equilibrium of mixed eluent components withinthe column packing. Let us therefore make some indirect conclusions concerning the pressure effects onsolvent-solventinteractions.Sincetheextentofpreferential solvation (sorption) is generally the function of interactions between all components ofthe multicomponent system,we can expect that thechanges in solvent-solvent interactions also influence the interactions between the sorbent and the solvent mixture. The possible effect of pressure on the solvent-solvent interactions can be illustrated bythe examples of azeotropic mixtures. It is known that the phenomenon of azeotropy is caused by the nonsymmetricity in the binary interactions A-A, B-B and A-B in the mixture of A and B. However for a detailed explanation of the immediate effects of pressureon preferential sorption, further experimental data must be collected underboth dynamic and static conditions. In conclusion, we shall mention some cases where the pressure effects shouldbeconsidered in liquidchromatographicexperimentalpractice, since the sorption equilibrium of mixed eluent components can be influenced in all situations, when the pressure is changed in liquid chromatographic columns suddenly or gradually, accidentally or deliberately. This may happen, for example, when the elution rate is altered and the column
138
Chapter
arrangement is changed, during sample applications without eluent bypass, but especially during stop-flow sample injections or during a majority of gradient elutions Admitting that thepressure influencesthe preferential sorption of the mobile phase components on the column packing, we must also expect some effect of the pressure on adsorption of the sample molecules within the liquid chromatographic column, even in the case of a single eluent. Consequently, the pressure variations could influence the retention volumes not only in mixed eluentsbut also in the single mobile phase. In spite of the fact that the changes in the retention volumes with pressure are expected to be generally unimportant in common liquid chromatographic systems, they may become measurable under certain circumstances. We do expect this case in the systems where the selectivity of a solvent is dynamically controlled by the addition of small amounts of a modifier to the mobile phase.
C. Optimization Methods Many optimization problems in column chromatography have been approached through several quality criteria. However, optimization criteria have a great influence on the success of an optimization. solve this problem, many optimization criteria have been employed as objective optimization functions. The chromatographic response function (CRF) was proposed to optimize separations of mixtures of isomeric octanes in gasliquid chromatography by Morgan [400]. Later, the chromatography optimization function (COF) was defined by Glajch [401,402] and the area overlapping function (AOF) by Knoll [403]. However the number of peaks is not considered in these optimization criteria. Watson and Carr [404] defined another CRF, which does consider the number of peaks. Berridge [405-4071 has used the CRF to optimize the mobile phase and to establish automated approaches to HPLC optimization. However, the composition of the mobile phase at the maximum for the CRF does not correspond to the optimal operating conditions. Therefore, a hierarchical chromatography response function (HCRF) is established by Smith and Lu [408-4111 using the simplex method [412,413]. Simplex is a method for finding optimum operation conditions in chromatographic separations. In a more recent paper, Lu [414] describes a new procedure based on this method, which incorporates not only depth-first and width-first intelligent search strategies, but also a logical algorithm for reflection, expansion, contraction, and movement ofthe simplex method towardsthe optimum. On the other hand, Hayashi in three recent papers [415-4171 applies the FUMI (function of mutual information) and TOCO (total chromato-
Liquid Chromatography
139
graphic optimization) in view of the optimization of liquid chromatographic variables (mobile phase compsition, column length, flow rate, detection wavelength and the amount of internal standard). In these papers, two types ofoptimal conditions are proposed: the +-optimal defined as the most precise condition among all the examined conditions and &optimal defined as the most efficient (rapid) condition and is described by the maximum of the information flow a (the amount of information transmitted in a unit time). From herein, and 8 are called precision and efficiency,respectively. Precision and efficiency, therefore, are an essential description of analytical systems intendedfor quantification. An analytical system set at an operating condition will take its own precision and efficiency, from which the analytical performance of the system can be known and evaluated. It is often said that precision is incompatible withefficiency; the fastest analysis can be accomplished at theexpense of the highest precision. The analytical roles of the chromatographic variables can be known from their own patterns in the 4-8 plots. Optimization of the mobile phase compositionis the most frequently studied subject in liquid chromatography. As shownfrom the +-a plots, the other chromatographic variables are not less important in the optimization than the phase composition. As far as reliable chromatograms are concerned, close examination of the 4-8 plots leads to the following conclusions:
+
1. The precision
+
+
is compatible with the efficiency 8 in manipulation of phase composition, column length, and detection wavelength and notof flow velocity. 2. Flow velocity isthe most influential factor on 8. In the caseof strong peak overlap and excessive information variation further optimization is necessaryfor establishing more efficiency(rapidity) of the assay. In the case ofchromatograms having many peaksdifficult to separate from each other, conclusion (1) holds in most cases. Recently Knauer Company (Germany) performed the CHROMDREAMO program for the selection of initial conditions and calculation of retention in reversed phase HPLC [418,419]. The CHROMDREAM software consistsofseveral blocks (windows): sample, draw, range, conditions, save conditions, and calibration. A file with volume and energy increments for more than structural fragments and more than 30 bond dipoles is also available. CHROMDREAM assists the chromatographer in order to establish the relationship between chemical structure and chromatographic behavior of a compound.
140
Chapter
When the chromatographer draws a structural formula on the PC screen, CHROMDREAMwill simulate a plot of the retention (k' or In k') of the drawn compound versus the concentration of the oganic solvent in the mobile phase. The chemical structure can be changed by the introduction of polar or nonpolar substituents to demonstrate how the change in the polarity or size of the component leads to a change in the retention and chromatographic behavior. CHROMDREAM gives the opportunity tocharacterize the selectivity of reversed phase columns with different packing materials. It uses the following equation for the calculation of a compound's retention and for calibration of columns: In k' = aS
+ b6G + c
(101)
whereby S is the surface of the cavity in the mobile phase wherea molecule is solved; AG is the molar interaction energy of one mole ofthe compound with the surrounding medium; a, b, and c are parameters of the reverse phase column used.From eq. 101 it can be concludedthat theselectivity of the separation of the compounds, which differ in their molecular volumes, increase with increasing value ofthe parameter a. The separation of some analytes with rather substantial differences in AG is preferable on the sorbent where the maximum value of the parameter b is obtained. It has been shown that the parameters a and b are very sensitive to the structure of a chemicallybondedphase and to the concentration of the hydrophilic groups in the surface layer. With the increasing number of hydrophilic groups on the packing material's surface, the values ofthe parameters and b decrease. Thus, a and b are responsible for both the selectivity of a separation and forthe column-to-column reproducibility. To determine the column parameters, the chromatographer can use several reference compounds (benzene, toluene, phenol, p-hydroxybenzaldehyde, etc.). Whenentering values of the capacity factors of the reference compounds, CHROMDREAMcalculates the column parameters. These parameters can be saved ina parameter's library and used for thecomparison of different packing materials, to predict the column-to-column reproducibility or to simulate the chromatograms of a mixture under the conditions of a calibration. If two column packing materials have approximately the same characteristics, the same values for the retention and the selectivity are obtained for a compound selected.Usersofreversedphasecolumns are able to calibrate their columns in order to predict the reproducibility, and manufacturers can calibrate their packing materials for quality tests. It is common knowledge that sometimes a correlation exists between compoundcharacteristics biologicalactivity. CHROMDREAM enables
Liquid Chromatography
141
the user to evaluate the correlation between a molecule’s size and its bioactivity, between the interaction energy of a compound with water and the bioactivity and, finally, the interaction of a compound with a hydrophobic surface and the bioactivity. In conclusion, this software represents a way for studying the relationship between the hydrophobicity and/or hydrophilicity of a compound and its biological activity.
D. Analytical and Preparative liquid Chromatography Whenliquid chromatographs first appeared on themarket, they were known by pseudonyms such as “amino acid analyzer,” “nucleic acid analyzer,” or “urine analyzer.” In the biochemical market, forwhich the instruments were developed, chromatographic instrumentation was not widely used, and most separations were done by using open-column, paper, or thin-layer chromatography (TLC). Open-column chromatography was time consuming and tedious, often requiring a large amount of sample if the technique was not carried out in a cold room, the constituents of interest could degrade before the separation was completed. Fractions had to be collected and the components detected and quantified by another method such as UV spectroscopy. Other disadvantages included the use of large volumes of solvents, low sensitivity, and poor reproducibility and resolution. When paper chromatography and TLC were used, some ofthe detection problems were solved. Very small samples could be analyzed, and the reproducibilityand resolution improved. The ability to assay many samples simultaneously, achieve faster separation times, and use smaller amounts of solvent made these techniques more advantageous than open-column chromatography. However, quantitation was still inadequate and resolution of similar compounds was difficult. Gas-chromatographs were available in the 1960s and 1970s, but because most biologically active compounds are nonvolatile, thermally labile, ionic, or of high molecular weight, derivatization was usually necessary. Unfortunately, in the derivatization step, errors could be introduced, and sometimes the quantitative results were questionable. Although on-line derivatization procedures were developed, GC was not used routinely in the majority of biochemical, pharmacological, or medical laboratories. To the analytical chemist, it was obvious that there was a tremendous need for an instrumental technique that could separate water-soluble, thermally labile, nonvolatile compounds with speed, precision,and high resolution. The development of HPLC was spurred by the discovery of DNA. A reliable technique was urgently needed for the separation and quantification of subnanoliter quantities of nucleotides from the hydrolysates of
142
Chapter
DNA and RNA. The separation methods availableat the 1970s were inadequate. By 1969 a limited number of HPLC systemswerecommercially available. Columns were unreliable -retention times and characteristics were not reproducible, not only in columns from company to company, but in columns from the same company. Pump flow rates were inconsistent, and thequestion of whether it was better to have constant flow or constant pressure was debated. UV and fluorescence detectors were developed and widely used, but for many biologically active molecules such as triglycerides, saturated oganic compounds, fatty acids, and carbohydrates, detection continued to be a problem. Moreover, there was no sensitive universal detector for HPLCas good as the GC flameionization detector (FID). Most researchers in biologically oriented laboratories continued to resist using HPLC. However, it was finding its way into analytical as well as a few biochemical, pharmaceutical, and medical laboratories. The development of microparticle chemically bonded packings was a major breakthrough in making HPLC a valuable technique for the life sciences, and the introduction of reversed phase packings made it a more universal tool t420-4221. High resolution separations that could not be readily accomplished by ion-exchange, adsorption, or normal phase-HPLC were achieved by using reversed phase-HPLC (e.g., the separation of nucleotides and their bases). Publications on the mechanism of reversed phase-HPLC (RP-HPLC) appeared, and reports on the use of HPLC and RP-HPLCwere publishednot only in analytical and chromatographic journals, but also in biochemical, pharmaceutical and medical journals. By the late 1970% HPLC was an accepted techniquein any laboratory requiring goodseparations [423].
1. Analytical HPLC In 1981 an article in Analytical Chemistry described a relatively new direction in modern liquid chromatography [424]. Since that time, microcolumn liquid chromatography, which was initiated during the late 1970s, has undergone extensive development.The main purpose of the above mentioned article was to acquaint the analytical chemistrycommunity withsome unique features of miniaturized liquid chromatographic systems and their potential for various separations and measurements. Microcolumn liquid chromatography is one of the several miniaturized separation techniques that have been under intensive development. The others are capillary gas chromatography, capillary supercriticial fluid chromatography, and capillary electrophoresis. Microcolumn liquid chromatography is now about fifteen years old. The initial developments toward miniaturization in the United States [425-4281 and in Japan [429-4311 were
Liquid Chromatography
I43
quickly followed by a number of researchers worldwide. Several monographs and review articles on the subject have quicklyappeared [432-4361. Although the various groups pioneering this research might have distinctly different objectives in mind,the most important advantages ofusing miniaturized columns became generally appreciated in a relatively short period of time. The major benefits of this technique are higher column efficiency, improved detection performance, easier coupling with uncommon detectors, and the ability to workwithsmallersample quantities. Priorities have changed overthe years as different applications have varied the emphasis of these unique capabilities of the miniaturized systems. Miniaturization is a general trend common to science and technology. Indeed, many developments in modern analytical chemistry have required miniaturization of instrumental components (in electrochemistry, spectroscopy, and separation science alike). Consequently, our ability to work with small dimensions (micrometers) and volumes (nanoliters and below) has improved dramatically in the past several years. Besides the obvious benefits in the area of column fabrication, miniaturization has made it feasible to exploit certain laser and microelectrode technologies for the sakeof improved detection. A scientific dialogamong the analytical disciplines has been mutually rewarding. Microcolumn liquid chromatography recentlyhashad a growing number of enthusiastic followers in spite of slow progress in the necessary instrumentation and commercialization. During the last decade numerous monographs on the subject appeared [437-4391, in addition to review articles [440-4441. The correct role of microcolumn liquid chromatography is not to replace conventional (4.6 mm i.d.) columns in modern liquid chromatography, a fact that analytical chemists increasingly appreciate. However, microcolumn liquid chromatography has certain strengths in a growing number of applications in which conventional liquid chromatography cannot effectively compete. Microcolumnliquid chromatography is viewed as one of the several miniaturized separation techniques that have recently been under intensive development.It is now emphasizedthat miniaturized separation columns, whether used in various forms of chromatography or in electrophoresis share similar technologies and instrumental requirements. This emphasis has been advantageous in all of these microcolumn separation techniques. The cloud of controversy that is perhaps typical for a new development no longer surrounds microcolumn liquid chromatography as it did in 1981, when the first feature article was published [424]. Although still primarily a research tool, microcolumnliquid chromatography is more widely accepted in various laboratories and for various sample types. It is
Chapter
144
a
b
C
Figure 12 Types of microcolumns: (a) open tubular capillary; stationary phase is a liquid or a finely dispersed solid; (b) partially packed capillary columns; particle adsorbent may be chemically modified; (c) tightly packed capillary columns; support with bonded phase.
one of the most active areas in analytical separation science, as evidenced by the steady increase in publications and presentations at both major chromatographic symposiaand specialized meetings. There are three types of microcolumns currently used in liquid chromatography(Fig.12):open-tubularcapillarycolumns,partiallypacked capillary columns,and tightly packed capillary columns. The tightly packed capillarycolumns(alsoreferred to asslurry-packedcapillarycolumns throughout this book) are now the most popular microcolumns used in liquid chromatography. Their introduction t445-4481 has significantly decreased interest in the other types of microcolumns. This type of microcolumn is made with fused silica tubingand is filled with various liquid chromatographic packing materials having 3-20 pm particle size. Being easier to prepare than partially packed capillary columns, packed capillary columns offer a more feasible way to avoid many of the problems of open-tubular capillary .columns (e.g., sample loadability and highly demanding instrumental requirements) while still retaining most the of advantages of microcolumns. A great advantage of packed capillary columns over open-tubular which must be very narrow (less than 10 pm) and coated with very thin film for a convenient mass transfer is their ability to handle both small and relativelylarge amounts of substances. The sample capacity of various packed capillary columns in is the range 0.1-1 .O pg per component, depending on the nature the column packing[449]. Some confusion in terminology still exists. The term “microcolumn” (i.e., a separation column with a typical i.d. as small as a millimeter) and “capillary” are equally used. The latter term is not necessarily restricted to open tubular geometry. The term “microbore,” an obvious misnomer, unfortunately has been associated by a number of workers with the 1 mm i.d. dimension.
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145
Compared to conventional HPLC columns, packed capillary columns present a notably improved separation power allowing resolution of complex mixtures [450,451]. The higher resolution power derivesfrom thepossibility of preparing and using longer columns because their higher permeability, providing therefore an elevated number of effective theoretical plates [452,453]. Although typical packed capillary column internal diameters are between 40 and 200 pm, columns with internal diameters as small as 20-50 pm were packed by Karlson[454] and Kennedy [455] and resulted in excellent performances. On this occasion it was shown that the reduced plate height of the packed capillary column decreases with the internal diameter of the column. In terms of reproducibility of packing, packing capillary columns are on par with and often better than the best conventional liquid chromatographic columns.It is possible to pack microcolumns reproducibly to a length of one meter with 5 pm reversed-phase materials yielding over 100,OOO theoretical plates [456] and with 5 pm silica or other polar materials such as.'diol, cyano, and amino-bonded phases yielding lower but reproducible efficiencies N/m). Size exclusion materials have also been used for packing microcolumnsfor theanalysis of proteins [457]. To use microcolumns, all parameters and instrumentation must be miniaturized. Among the advantages of microcolumn HPLC is the ability to work with very small sample volumes and reduced flow ratesand solvent consumption. In addition, because of the small volumes of effluent from microcolumns,miniaturizedelectrochemical or laser-baseddetectors or mass spectrometers can be interfaced with HPLC more readily. Thus, using HPLC/MS, quantitative data can be obtained simultaneously along with peak identification and structure determination. It is also possible to use multidisciplinary techniques such as HPLC/GC/MS if very small effluent volumes are involved. Because cost benefitsare obtained when small volumes ofthe mobile phase are used, exotic and usually expensive solvents can be usedto facilitate a different separation. However, researchers are still trying to solve some problems in capillary column HPLC: the lack of flow rate reproducibility, the need for improved gradient elution, and accurate introduction of minute sample volumes. In assessing the separation potential of various microcolumns, one must applyappropriate criteria for column performance. Whetherthe characteristic dimension of a microcolumn the is particle size (packed columns) or thecolumn radius (opentubular columns), under optimum linear velocity of the mobile phase the plate height, H, is roughly equal to twice the characteristicdimension. To evaluate the column's separation potential based on its H-valueis misleading ifthe column length,L , and the analysis
Chapter
146
time, t , are not considered. A large number of theoretical plates, N = L / H , is often achieved in liquid chromatography at the expense of long analysis time. Comparison of different microcolumns under dissimilar conditions of chromatographic analysis is quite adequately obtained usingthe and Knox so-called separation impedance, E, introducedbyBristow [458,459].
E =
tApH2
N27( 1
+ k ) K o = h*+
where Ap is the pressure gradient required for the separation, 7 is the solvent viscosity,and k is the capacity factor. It is shownthat the separation impedance isproportional to the square of the plate height (H) divided by the column permeability(KO),or, alternatively, is equal to the square of the reduced plate height( h = H / d ) multiplied bya column resistancefactor, 4 = d2/Ko,where d is the particle diameter or the i.d. of an open tubular column. Table 14 gives estimates of such values for different types of microcolumns [459]. The obvious mass transfer considerationsfor thediffusion-controlled sorption-desorption kinetic phenomena in chromatographic columns have longcentered around particlesize as the characteristicdimensionof a packed column in liquid chromatography.The remarkable success of modern liquid chromatography is, in fact, directly attributable to miniaturization of packing particles. Considerably less attention was paid initially to the potential benefits of decreasing column diameter. In fact, using widely accepted packing procedures, small column diameters (and greater column lengths) generally yield inferior results; hence the extensive use ofthe 0.25 m 4.6 mm i.d. column in the practice of modern liquid chromatography. This is at last a partial explanation of why the pioneering studies by
Table 14 Comparison of the Theoretical Performancesof Different Column type
Column Conventional or small-bore packed capillary column Semipermeable packed capillary column Open-tubular capillary column Source: Ref. 459.
hmi"
Emi"
2
500-1 ,OOO
2
150
0.8
32
2000
20
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147
Scott and Kucera [425,426] employing 1 m segment columns with1 mm i.d. initially were met with considerable indifference. Because a decrease of column i.d. is continuously emphasized for a variety of reasons, tightly packed capillary columns based on the fusedsilica tubing material and various liquid chromatographic packings are increasingly popular. For reasons that are not yet fully understood, the column tubing materialappears to play a considerable rolein the efficiency of a slurry-packing process, and the fused silica columns originally developed for capillary GC currently provide the most desirable results [460]. These slurry-packedcapillarycolumns,introducedbyresearch groups in the United States and Japan [461-4641, may well be a key development in the microcolumn liquid chromatographic field. The technology of tightly packed capillaries has improved substantially overthe past several years. Typical column diameters are between 200 and 300 pm, although columns as small as44 pm i.d. were recently packed and resulted in excellent performances [454]. Such columns can now be slurry-packed to a length of one meter or even longer, yielding a total number of theoretical plates over 100,000 [465]. Extremely high reproducibility the of column parametersfor reversedphase columns has been demonstrated [453]. A surprising finding is that reduced plate height of slurry-packed capillaries decreased as a function of the column radius [454]. Although most successful studies have thus far been conducted with reversed phase columns, Andreolini et al. [449]have also demonstrated respectable efficiencies for 5 pm silica adsorbent and other polar materials. This study demonstrated that considerable different packing procedures may be neededfor packing materials of diverse chemical natures. Partially packed (semipermeable) capillary columns (Fig. 10) are prepared using a special column technology. A narrow-bore, thick-walled glass tube is first tightly packed witha suitable sorption material. Subsequently, a glass-drawing machine is usedto draw a length of the packed tube into a capillary of suitable diameter [427]. Individual particles are drawn inside this capillary, and a number of them actually become imbedded in the column wall at the melting point of the glass. Kinetic evaluation of such a column indicatedthat the column performances wasa sensitive function of both thei.d. and nominal particle size[466]. Irregularly shaped silica particles gave consistently higher efficiencies than spherical materials, indicating some importance of irregular flowpatterns attributable to the zigzag inner structure of these columns. As shown in Table 14, irregularly packed columns are theoretically attractive becauseof their low values ofthe column resistance factor and separation impedance. Under ideal circumstances, they should combine the best properties of
Chapter
148
tightly packedand open tubular columns (i.e., an adequate sample capacity combined with high column efficiencies). However, studiesof semipermeable packed capillaries have been done less frequentlythan studies of slurrypacked capillary columns, for several reasons. Because of flexibility, the polymer-coated fused-silica tubes are more popular than the more fragile glass capillaries. Certain fine details of a proper capillary drawing procedure seemdifficult to reproduceindifferentlaboratories, and specific chemical properties of the column materials can only be adjusted after the drawing process, through a suitable reaction or a sequence of surface treatments, making the overall process somewhat tedious [467]. Not until 1986, wereresearchersable to draw inside the glass capillaries packing materials smallerthan 10 pm [468]. Prospects for partially packed capillary columns have gradually improved. Originally only alumina particles were employed, because it seemed unlikely that siliceous particles could survive the high glass-drawing temperthe study by atures without a lossofsurfacesilanolgroups.However, Hirata et al. [467] proved this to be a minor problem, because enough surface activity was retained by silica to facilitate preparation of the stationary phase with various selectivities by an in situ modification of the drawn columns. Additional improvements subsequently were made by Tsuda and coworkers [469,470], who succeeded in drawing spherical particlesinto the glass tube to form a denser particle distribution while maintaining good permeabilities. Semipermeablepackedcapillariesremain an interestingsubjectof chromatographic studies. Typical plate height equationsdo not adequately describe their behavior. A kinetic study by McGuffin and Novotny [466] pointed out some unconventional roles of particle shape and column i.d. As suggested by Knox [468] about packing very small particles, the columns are likely to attract further attention [469]. Although the open tubular column represents the simplest column geometry and the characteristic advantage of permeability (see Table 14) the use of such columns in liquid chromatography has been extremely rare. The Golay theory [471,472] of open tubular chromatography reveals that the column diameter, d,, and the stationary phase film thickness, dF,are essential for counterbalancing slow diffusion in both phases:
H = U
+ 6k + l l k ’ + 1 96(1 + k)’
dcu
D,,.,
k
2 (1
di
-U + k)’DS
(102)
where U is the mobile phase linear velocity.The solute mobile phasediffusion constants, DM,are on the order of 10”-10-6 cm2-s”, necessitating columndiametersbelow 10 pm. Typical values of the solute stationary
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149
phase diffusion constants,Ds, which are somewhat smallerthan D,,, values, impose fewer restrictions the film thickness. Time of analysis, t , is expressed for a given column diameter and pressure gradient, Ap, as a function of column efficiency bythe following equation:
Therein lies the main attractive features open tubular liquid chromatography. Because of the high permeability of such columns, extremely high efficiencies can be attained in reasonable analysis times. In spite of the obvious technological difficulties in the realization of practicalopen tubular liquidchromatography,researchremainsactive, and, in fact, considerable progress has been made during the last ten years. Following the earlier assertions [473] that the Golay theory is applicableto open tubular liquid chromatography, several groups have prepared such columns through a variety of chemical approaches in smaller dimensions. Glass capillaries, usedin much of the early research, have yielded gradually to the more popular fused-silica tubes that are now available in small dimensions. The technologyofliquidchromatographicopen-tubularcolumns greatly benefits from the following procedures developedfor capillary GC and supercriticalfluidchromatography:surfacetreatment for inducing wettability, deactivation (removal of reactive sites), coating techniques, and stationary phase immobilization. Although much work the preparation of columns with 30-50 pm i.d.’s has been published, such procedures (including surface etchingand treatment with various silanes) become increasingly difficultwhen smaller columnsare used because of cloggingand ineffective removal of byproducts. However, some innovative approaches to the column technology at about 10 pm i.d. and below have resulted in efficiencies the order of lo5 theoretical plates [474]. The typical flow rates used with 20-32 pm i.d. packed capillary columns are in the range 1-10 pL/min. The low flow rates impactto microcolumn liquid chromatography a unique set of advantages, starting with a substantially improved mass sensitivity with miniaturized concentrationsensitive detectors [475] (UV absorbance, fluorescence, and electrochemicaldevices).Laserinducedfluorescencedetectorsseem to be the most attractive as far as sensitivity and versatility are concerned [476,477]. The low flow rates account for better compatibility columns with certain detection techniquesnot strictly typical of liquid chromatography (e.g., GC detectors, such as the flame-based and electron capture detection) [478-
Chapter 3
I50
4801 as well as an easier coupling to mass spectrometry [481-4831. Flow
rates of a few pL/min also favor the coupling of packed capillary columns with other separation techniques (e.g., micro-LC-HRGC, micro-LC-TLC) [484]. Another advantagederived from the flowratesemployedis the drastically reduced consumption the mobile phase, allowing the use of expensive (ultrapure, deuterated, etc.), exotic (chiral), or toxic and environmentallyhazardoussolvents. The smallcolumndimensionsimply a lower adsorptive behavior due to the lower amount of stationary phase used in these microcolumns, and the chemical inertness of fused silica column walls guarantees the entire recovery of the injected sample, symmetrical peak shape, and, therefore, better quantitation. Packed capillary columns require low sample volumes. This technique is therefore a valuabletool formicromanipulation in modern medicine and biotechnology or whenever sample availability is limited [485]. When new chromatographic methods are developed, advancesin column design (the heart of the system) often necessitate dramatic changes in related instrumentation. This point cannot be overstated for microcolumn liquid chromatography. A decrease inthe column i.d. results in drastically reduced flow rates ofthe mobile phase: mL/min flow ratesare characteristic for conventional liquid chromatography, whereas only pL/min are used with typical packed capillary columns. Eventually,the flow rates required by open tubular liquid chromatography, with optimum column diameters, are approximately 10 times lessthan those for packed capillaries.The volumetric variance a microcolumn is given as u,l,,,
=
HL
(104)
where is the total porosity (typically, 0.85 for a tightly packed column and 1.O for anopen tube) and r is the column radius. Representative values of the column variance are 0.278 for a typical slurry-packed capillary (1 m 260 pm i.d., packed with 5 pm particles) and 2nL’ for an open tubular column (5 m X 10 pm i.d.) [486]. Because efficiency of the overall separation system is determined by the sum of the column variances caused by extracolumn band-broadening, it is easyto understand why inadequate equipment can severely limit the use of such small chromatographic columns. The extracolumn contributions attributable to the sampling volume and detection cavity must be reduced to the nanoliter range for most currently used packed microcolumn. A contribution of Manzand Simon [487] indicated that 6 pL cell volume is necessary for an open tubular column (130 cm X 3.5 pm i.d.) producing lo6 theoretical plates. As discussed inthe papers of Manz [487] and Guiochon [488], additional sources of extracolumn band-broadening, such as laminar dispersion, irregular flow patterns, and, occasionally, the system’s
Liquid Chromatography
I51
time constant, can all havea negative influenceon the separation efficiency. Consequently, microcolumn systems must be designed withthe utmost attention to eliminating these sources of band dispersion. Conventional liquid chromatographic equipment cannot be used with microcolumns unless it is modified extensively. Pioneering studies by Japanese researchers [429-4311 already have provided numerous ideason liquid chromatographic miniaturization. Various modificationsofcommercialinstruments for workwith 1 mm i.d. columns have also been described by Scott and Kucera [489]. With an increased emphasis on the use of ever-smaller columns, instrumental challenges become multiplied. Nevertheless, remarkable advances in this direction have been made over the past several years. These include the design of reliable micropumps, high-pressure valves with sampling loops dispersing a small fraction of a microliter volume, small-sized fittings, and miniaturized detectors. Precision and accuracy of sampling volumes depend primarily on the stability ofthe flow rate delivered bya micropump. Likewise, reproducibility of retention times in long chromatographic runs is strongly influenced by the solvent delivery system.As shown in the study of Boraand coworkers [465], some currently available micropumps provide satisfactory results in terms of flow rate reproducibility. Syringe pumps, however, generally are preferred. Carrying out gradient elution in miniaturized liquid chromatography is often more complicatedthan using conventional solvent delivery systems. Some modifications ofthe readily available solvent delivery systems include stepwise gradients[490], split-flow operation[491], and miniaturized single or multiple experimental dilution chambers [492,493]. Specifically designed commercial instrumentationin this area would bea most desirable advance. Introducing small sample volumesand amounts into microcolumns is mandatory for preventing column overloadingand minimizing the width of input functions with respect to the column variance. Although the sample capacities of various packed capillary columns are adequate ( l 0 - l 0 g) per component, depending on the nature of the column packing, for most detection techniques, small bore open tubular columns necessitate considerablysmallersamples and highlysensitivedetectorssuch as those based on fluorescence and electrochemical processes. The maximum permissible sample volume can be estimated from the geometrical characteristics of a particular microcolumn or from empirical measurements; they rangefrom small fractions ofa microliter for slurry-packed capillary columns[486] to as little asa few picolitersfor the smallest bore open tubular columns [487]. Obviously, direct sampling procedures are rarely used to deliver a desired sample size to the microcolumn. The moving injection technique [494],
152
Chapter
using electrically activated injection valves, appears to be adequate for reproducible sampling in packed capillary columns; however, split injections and heart cutting devices [495] are currently needed for smaller microcolumns (e.g., open tubular columns). Permissible volumes and geometries for detectors are also given by the columnvariances[486]. In the past decade, numerous studies were devoted to the miniaturization of conventional detectors (based on UV adsorbance, fluorescence, refractive index, electrochemical processes,etc.) as well as to specific designof new detectors for microcolumn liquid chromatography. Many liquidchromatographic detectors have now been drastically reduced in size, from microliter to nanoliter volumes and below. Oncolumn detection is strongly preferred whenever some feasible designs have been reported in which the solute band is probed directly on the column packing or immediately at the point of elution [496-4981by a narrow optical beam or an extremely small microelectrode [499-5011. Postcolumn chemical derivatization, a common approach in the practice of modern liquid chromatography had only a limited scope with microcolumns because ofband-broadening problems. Miniaturization of liquid chromatographic detectors has far reaching consequences for detection performance. The dramatically reduced flow rates provide someunusual opportunities, ranging from the enhanced mass sensitivities of the concentration-sensitive detectors to the adaptation of certain detection principles successfully used with GC (flame and flamebased detectors or mass spectrometer) and to entirely new detection technologies. The most important and commonly used liquid chromatographic detectors (UV absorbance, fluorescence, and electrochemical devices) are concentration sensitive that adecrease in their volume for small diameter columns is beneficial in terms of substantially improved mass sensitivity. Sensitivity enhancement (the ratio of the maximum solute concentration, C,,,,, within the detector cells) favors microcolumns overconventional columns because oftheir smaller i.d. [427].
It has been pointed out repeatedly in the recent literature that a column diameter decrease from 4.6 to 1 mm results in a substantial enhancement of mass sensitivity, and the use of capillary columns provides dramatic improvements for sample-limited analytical situations. Obviously, in cases where column capacitylimitations exist and large, diluted samplesare necessary for trace analysis, microcolumns are not preferable unless they are coupled witha suitable sample enrichment technique. It often surprises those unfamiliar with microcolumn liquid chroma-
Liquid Chromatography
I53
tography that even a UV absorbance detector (when properly designed and miniaturized) can be very useful. On-column UV detection, in which a part of the capillary column is used as an optical window, often yields subnanogram sensitivity [502], in spite of extremely small path lengths. In a carefully engineered flow cell that can be connected to 200-300 pm i.d. slurry-packed capillaries, the minimum detectable quantities are approximately 10 times lower than those with the cross-flow detectors. Likewise, miniaturizationofspectrofluorometricdetectors and photodiode-arraybased devices results in expected sensitivity improvements [503-5051. Miniaturizedelectrochemicaldetectors and variouslaser-baseddevices appear to be essential to progress in ultrahigh-sensitivity chromatographicmeasurements(i.e., amounts belowg). The need for such measurements is becoming increasingly obvious in the field of modern biology and medical science. Some indications exist that theart of miniaturized chromatography and highly sensitive detectionare now coming closerthan ever before to the situation predicted by the Nobel Laureate A. P. Martin: “ . . the appetite of the chemist to work on a small scale will grow as it becomes more possible. He will be able to analyse and experiment on a single cell[5061.” Among the best examples ofthe use of microelectrodesin liquid chromatography are the ion-selective electrode of Manz and Simon [499] and the carbon-fiber electrode reported by Knecht et al. [500]. Both groups used open tubular columns with extremely smalli.d.’s and with the type of an even smaller microelectrode positioned at the column outlet. Calculations in a study of Marz and Simon [487] indicated an effective detector volume of a few picoliters capable of detecting iodide ion inas little as 7.6 10 -l6 g. In the case of the carbon-fiber electrode [500] inserted directly in the column outlet, almost 100% coulometric efficiencies were achieved because the solutes passed inthe immediate vicinity ofthe fiber. In time, additional microelectrode devices undoubtedly will be developed to cover a range of substances in selective detection. It has become possible to record current-voltage characteristics for the solute emerging from microcolumns [5071. Numerous liquid chromatographic detectors that use various lasers have now been reported in the literature [508,109]. Laser technologiesnaturally combine with microcolumns because of the highly collimated nature of laser beams. Nanoliter to picoliter volumes thus are easily probed at the column’s outlet. Whereas thermal lens detection, refractive index, light scattering, and other techniques have suggested and initially explored for either conventionalor l-mm i.d. columns, laser-induced fluorescence seems to be the most attractive as far as sensitivity and versatility are concerned. The phenomenal goal of detecting some 22,000 molecules of a fluores-
.
154
Chapter
cent dye in a (nonchromatographic) flow system is being approached in microcolumn liquid chromatographythrough a variety of laser fluorescent methodologies [5 101. These developmentsare primarily concerned withoptimum detection geometries, exploration of the most practical laser systems, and chemical derivatization methodologies for the preparation of highly fluorescentand stable solutes. The miniaturized cell designs for laser-introduced fluorescence measurements reported in the literature include the falling jet geometry [51 l], the sheathflowarrangement [512], and variousfiber-opticalprobes [513,514].Because of its simplicity, the last approach is becoming increasingly popular. The helium-cadmium laser (used at either 325 or 442 nm) and the argon ion laser are now most favored by the research groups involved with this type of detection; however, as new laser sources become practical they should also be considered. Although monochromaticity ofthe laser light may be advantageously usedinsomehighlyselectivechromatographicmeasurements,generally there are only a few cases in which the available light frequently coincides with the maximum excitation ofthe molecular species of interest. However, if the initially nonfluorescent molecules can be converted to fluorescent derivatives, extremely high sensitivities can be achieved. This strategy of matching the laser wavelength and “tailored” excitation maxima of solute derivatives has been successfully explored by Katlsson et al.[515]through the synthesis of reagents for steroids and prostaglandins [515],bile acids, and primary amines[5161. Microcolumns that are characterized by flow rates aoffew microliters per minute or less are eminently suited for work with various flame-based detectors plasma devices [517].The sensitivities of these detectors are typically 1-2 orders of magnitude lower than those encountered in gas chromatographic analysis with flame photometric and thermoionic detection principles [ 5 18,5191. Substantial improvements in the sensitivity of flamebasedmicrocolumnliquidchromatographicdetectors are likely to be achieved through better solvent nebulization techniques [520].Only marginal success has been achieved with transport-type detectors (based on moving wires, bands, discs, etc.) in conventional liquid chromatography, because ofthe difficulty of gettingthe transport medium to accept the total column effluent (typically, 1 mL/min). Once again, microcolumn liquid chromatography is a preferable approach, because the entire column effluent can be depositedon a suitable matrixfor thefollowing flame ionization detection [521]or infrared spectroscopy [522,523]. The current advances in liquid chromatography/mass spectroscopy is high, and there is a general feeling that microcolumn liquid chromatography could be a key to progress in this area. Some technical aspects and
Liquid Chromatography
155
directions of microcolumn liquid chromatography/mass spectroscopy have been reviewed by Tsuge [524] and other authors [ 525,5261. Their results indicated excellent sensitivities together with some degree of control over the nature of molecular fragmentation. A typical and commercially available microcolumn liquid chromatograph is produced by Carlo Erba as Carlo Erba Instrument Micro LC 20 [527]. This device isa dedicated modular instrument designedfor isocratic or gradient elution operations with packed capillary columns. Figure shows a schematic diagram ofthe system ina binary configuration. The System 20 solvent delivery unit, Phoenix 20, consists of a microprocessor-controlled master syringe pump and up to three slave syringe pumps, controlled and piloted bythe master pump, for gradient configuration up to four solvents. Each syringepump has a capacity of 20 mL, with the syringe pistons driven by a stepping motor capable of achieving very precise displacement. Phoenix 20 can be operated in controlled flow or controlled pressure mode. Flow rates in the range from l to 4000 pL/min are selectable in 1 pL/min steps with a minimum individual flow rate of approximately 30 nL/min. Pressure up to 50 MPa can be selected in 0.1MPa increments. The Phoenix 20 can perform flow, pressure, and composition gradients. Rather than using check values, the pumps use unique
2 1
Figure 13 Schematic diagramof Carlo Erba Instruments Micro LC System 20 in binaryconfiguration; 1, Phoenix 20; 2, solventreservoirs; 3, samplingvalve; 4, micro-UV vis detector. (Adapted from Ref. 527.)
156
Chapter3
electronically controlled multifunction valves that provide automatic, unattended syringe operations (e.g., priming, purging, and filling). In multiple cycles operation, the pumping system evaluates before each run theexisting content in the cylinders and the amount of solvents needed for the next run. Ifnecessary,itautomaticallyrefills. Pump cylinders can be easily thermostatted for a better flow rate precision at extremely low flow rates. Proprietary low volume(5 and 10 pL) static mixing chambers are used for homogenizing solvent streams. Introducing small sample volumesand amounts into packed capillary columns is mandatory for preventingcolumnoverloading and to avoid , large variances. It is also important to inject only a portion of the volume contained in the sample loop because a sample volume injected totallyinto the column has an exponential decay profilethat negatively influences the peak shape. Indeed,the laminar flow ofthe displacing mobile phase causes the injected sample to be dragged along the wall of the sample loop, producing tails on the eluting peaks. Consequently,the moving injection technique is used [409]. A four-port, internal-loop electrically actuated injection valve (Valco Instruments) witha 60/200 nL rotor is used for sampling. Aprogrammablevariablewavelength UV-VIS detector,MICRO UVIS-20, equipped with an on-column flow-cell, having nL illuminated volume and 0.25 mm pathlength, was employed. The capillary columns were produced by LC-Packingsand Alltech. Reproducibleliquidchromatographicmeasurements are related to flow reproducibilityand solvent composition reproducibility.In pack capillary liquid chromatography where the flow rates are in the low pL/min range, the instrumentation requiredfor achieving highly reproducible liquid chromatographic measurements representsa significant departure from traditional approaches. It has to fulfill specific requirements, namely,an accurate, reproducible, and pulseless flowrate delivery in the range suitable for packed columns, and minimum extracolumn band broadening. In the last few years remarkable advancestoward dedicated systems with miniaturized and optimized components have been made. These include the design of syringe micropumps, high-pressure injection valves with low sample loop volume, small size zero dead volume fittings, low-volume mixers, and miniaturized detectors. The overall performance ofa chromatographic system is given by the sum of the column varianceand the variances caused by extracolumn band broadening.With the reductionof the columndimensions, and consequently, the operating flow rates, it is easy to understand that extracolumn contributions attributable to sampling volume and detection cell as well as deadvolumesinconnectingtubesmustbereduced to the nL range in order to avoid band broadening. Therefore, the chromatographic systems
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157
employed with packed capillary columns must be designed and operated with the utmost attention to minimizing or eliminating any sources of band dispersion. ConventionalHPLC instruments cannot be used with microcolumns unless extensively modified.In fact, many problems arisewhen working with conventionalHPLC instruments at flow rates below100 pL/min. There are basically two approaches to packed capillary liquid chromatography: the adaptation of conventional instruments and the use of dedicated systems based on syringe pumps. The flow-splitting technique is the most frequently usedway to modify conventionallyHPLC instruments for working at flow rates of a few pL/min. As described by van der Wal and Yang [491], the splitting ofthe flow output before the injector was done by means of two resistance flow paths, one at high resistance defined by the packed capillary column and the other at low resistance defined by a restrictor column. In this way the major part of the eluent was allowed to by-pass the analytical column. The precision withthe instrumentation operating in the constant pressure mode was found to be strongly dependent on temperature effects. In addition, with the split-flow technique frequent control of the actual flow through the packed capillary column was required because it was not really constant. In fact, the actual flow rate through the microcolumn was influenced by changes in the microcolumn permeability that modified the imposed split ratio and consequently the flow rate. Although modifications of conventional HPLC instruments improve their usefor microliquid chromatography, many of the problems associated with reciprocating pumps still remain (e.g., check valve related troubles). In addition, their use for packed capillary liquid chromatography severely limits the possibilities of this technique,further limiting the ease and flexibility of system operation. A dedicated miniaturized instrumentation based on syringe pumps appears to be the best approach to packed capillary liquid chromatography. Syringe pumpsoffer the advantages of freedomfrom pulsations (necessary with electrochemical, GC-type, high-sensitivity UV, and mass spectrometry detectors) and thecapability of pumpingat very low flow rates.The Phoenix 20 provides reproducible, accurate,and pulseless flow rates inthe range suitable for packed capillary columns. As in conventional HPLC analysis, the retention in packed capillary liquid chromatography is mainly controlled by gradient elution. Practical gradient elution with a solvent flow of just a few pL/min is a delicate problem. The miniaturization and optimization of the solvent delivery system for gradient elution is among the most important objectives of instrumental development in packed capillary liquid chromatography. Initially, experi-
158
Chapter
mental equipment consisting of a syringe pump and various homemade devices for realizing mobile phase composition gradients were developed. A stepwise gradient profile [490] was the first acceptable solution, although filling a series of miniature reservoirs, containing different solvent compositions,outside the instrumentwasextremelytedious and cumbersome. Later, with the exponentialdilutionprinciple,small-volumecontinuous gradient elution methods were realized[493]. However, this type of gradient is not very flexible. Tandem or multiple syringe pumps are attractive for generating gradient profiles in packed capillary liquid chromatography because of their pulse-free flow rate delivery. This allows the use of lowvolume static mixers for homogenizing the solvents, and for the accuracy and reproducibility of the delivered flow rate. The Phoenix 20 is designed for gradient analysis with packed capillary columns. In order to accurately realize any type of gradient profile, the syringe pumps are controlled and piloted by a single electronic module that controls each individual pump flow rate for reliable delivery ofthe imposed gradient curves. The reproducibility of retention times in gradient elution requires precise control of the variation of the mobile phase composition with time (gradient profile) and flow rate. Clearly, all thesefactors are a function of instrument design. With syringe pumps, two factors have to be considered: eluent compressibility and time necessary to reach the final steadystate flow and pressure conditions. It is known [490,493] that solvent compressibility could limit composition and flow accuracy and influence the time necessary to reach the final steady-state flowand pressure conditions. Although the compressibility of a liquid is small, its effects are greatly influenced by the solvent volume presentin the reservoir. The Phoenix 20, using microprocessor-controlledhigh-pressure valves, hasthe capability to partially fill the 20-mL pump cylinders with the amount solvents necessary for one analyticalrun and automatically refillto the same level before the next run. The amount of solvent necessary for one single run is determined on the basis of a simple calculation if the pump is operating in the controlled flow mode, or on the basis of liquid consumption during the previous cycle if operating in controlled pressure mode. In this way the influence on the compressibility ofthe solvent volume present inthe reservoir is drastically reduced. The steady-state time becomes larger with increases in reservoir volume, eluent compressibility, final back pressure of the system, and piston movement. Therefore, low-volume reservoirsare preferred. Relatively long periods of timeare necessary to reach the final steady flow rate and pressure conditions if no precautions are taken, such as prepressurizingthe syringe. The Phoenix incorporates a prepressurization function (target pressure),
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159
allowing steady conditionsto be achieved very quickly by having the piston speed up initially to pressurize the system to a target predetermined on previous runs. Before the execution of a gradient analytical run, all the pumps involved start to simultaneously compress their respective solvents at flow rates that are proportional to the volume of solvent contained in each syringe pump. This is performed order in to avoid crossflow contamination in the pumps. The exact and reproducible solvent composition, given by the high precision and constancy of the flow rate, and the effective mixing action assured by the micromixer, yield accurate and repeatable gradients evenat flow rates of a few pL/min. Homogeneous mixing of solvent streams can be achieved either by static flow mixing devices or by actively stirred dynamic chambers. The pulse-free flow generated by syringe pumps allows the use of simpler static mixers. The quality ofthe gradient can be influenced by two factors: the delay volume (time) and the response volume (compositional accuracy).The delay volume can be defined as the dead volume between the initial mixing point of the liquid streamsand thecolumn. Althoughthe delay volume can besubtracted from the chromatogram, itdoeslengthen the chromatographic analysis by addingadditional time to both the gradient elution and to the reequilibration to starting conditions. The second factor influencing the quality the gradient is the response volume. It is indicative of the ability of the system to respond to a sudden change in mobile phase composition. It can be experimentally determined by measuringthe volume from the startof the gradient until an arbitrary final solvent composition value has been reached. Too large a volume can distort the imposed gradient profile. In conclusion, it isextremely important to have low-volume mixers in order to minimize the delay volumeand to minimize the composition accuracy. Permissible volume for detector cells are determined by column variance. Many liquid chromatographic detectors have been miniaturized from pL to nL volumes. On-column detection, in whicha part of the capillary column is usedas an optical window, is strongly preferred whenever feasible. Among the numerous detectors that can be employed in microliquid chromatography, miniaturizedUV-Vis and fluorescence detectors are theones most often used. On-column UV detection often yields subnanogram sensitivityin spite of extremely smallpath lengths. MicroUVIS 20 (Carlo Erba) is a UV-Vis detector dedicatedto packed capillary column liquidchromatographs and it encompasses allthe features demanded by microliquid chromatography: namely, on-column detection,
\
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low detection volume, and low temporal dispersion (quick response). In addition, MicroUVIS has extensive programming possibilitiesthat allow maximum flexibilityand capabilities. The quality of a detector can be estimated in terms of sensitivity to refractive index changes, linearity,and sensitivity. For a given wavelength, the refractive index ofthe mobile phase can varyon several levelsthat can be associated with analytical parameters such as theuse of gradients, solute concentration, or temperature variations. The high-level variations of the refractive indexare observed during gradient elution when water is replaced with organic solvents, producing baseline drift. MicroUVIS has a special optical geometry that renders the detector insensitive to refractive index changes, resulting ina stable baseline. Interest in multidimensional separation technique has gradually increased duringthe past decade.To achieve betterseparation of components in extremely complex mixtures, various separation principles are being applied in coupled-column systems.In one such direction, where liquid chromatography is combined with capillary GC, it is a convenient coincidence that the volumetric flow rates of typical liquid chromatographic microcolumns (pL/min) form nearly ideal sample deliveryfor capillary GC columns [ Microcolumnliquidchromatographyhaspromptedresearchers to pursue some interesting directions in the field of separation science. The exploration by analytical chemists of increasingly smaller dimensions for the sake of instrumentation with new capabilities will likely result in new solute-sensing devicesand sample handling techniques. In thecolumn designarea, both the packed capillaryand open tubular approaches will undoubtedly be pursued further. It has already been demonstrated that microcolumn separation methods hold the key to improvements in component resolutionand high-sensitivity detection for relatively small organic molecules. Development of similar capability for larger molecules suchas oligomers and polymers appears to be the next logical step.
2. Preparative HPLC The first synthetic preparative liquid chromatographic separations to attract more generalattention, about years after the discovery of chromatography,werethoseofKuhn and Winterstein followedby Zechmeister and Cholonsky Stein and Karrer and Strong These researchers separated gramamounts of mixtures of plant pigments and other natural products. All of these separations involved colored substances that could be easily detected in a glass column. When the separation was complete, the column packing material was pushed out of the
Liquid Chromatography
I61
column and the visible bands cut apart and extracted with a suitable solvent. The most important preparative separations performed by these authors are listed in Table 15. The data listed in Table 15 reveal the absence of silica gel. From the quoted adsorbents only Alz03and Fluorisil are still used today. After WorldWar I1 preparativeliquidchromatographyevolved slowly. Slight pressure (lessthan 1 bar) was often applied, and step gradient elution was usedrather than column extrusion.Preparative thin-layer chroTable 15 Survey
Sample
Preparative Separations for Period 1931-1936
Ref.
Column dimensions: diameter/ Adsorbent length, cm
30 mg egg yolk pigments in 500 cm3C S ~ 10 mg carotene from carrot rootsin 40 cm3benzinea mixture cholesterine-ergosterine (5.6 mg) in 300 cm3benzenehexane ( M ) Oleanol (C2,H,0H) Oleanylene (C,H,) in benzine 8 g geraniol-limonene in cm benzine 3 g chlorophyll (a and b)in 15 cm3 benzine-benzene 1 g chlorophyll in 2000 cm benzinehexene (4/1) Carotene 1.5 g raw peonine in 200 cm H 2 0 50 mg raw capsanthin in100 cm3 CS2 Extract from 200 g paprika peelings in CS2 Extract from 20 g unsaponified paprika coloring waxes 2.2 carotene from carrot rootsin 2000 cm3petroleum ether
7/ -
CaCO,
2320
Fibrous
5315
A1203
4.5/14 5.5/12 12385 15350
-
A1203
Powdered sugar Powdered sugar Ca(OH),
-
-
5.5/21
CaCO,
-
-
4.6/30.6
MgO cellulose
+
*Benzineis an older German wordfor the lightest petroleum fraction with boiling point about 4OOC.
I62
Chapter
matography (TLC) also was used extensively. During this period, silica gel was introduced as a new stationary phase and theparticle size ofthe column packing material-which during Tswett’s time was very small (1-10 pm)was increased to 200-500 pm. Suchpreparative liquid chromatography in a glass columnis at still in use in many laboratories [537]. Although someverylarge-scalemovingbed industrial separations [538], such as those used for molasses or xylenes, could be called chromatography, theseprocedures are inefficient for phase exchange and are clearly different from high-performance preparative liquid chromatography. From the beginning Tswettwas aware of the preparative possibilities of chromatography. He designed approaches for the separation of larger though still small amounts of plant pigments for analytical work. Tswett, as a botanist, left to others the chemical investigation of the substances separated by his method. However, preparative liquid chromatography in the latest period (1950 to the present) has not settled on asingle solution; this is not surprising as sample requirements and difficulty of separations are widely varied. Industrial liquid chromatography with 50 to 150 cm diameter columns has been investigated [539,540]. As in gas chromatography efficiency of these large diameter columnsis increased by using baffles to promote radial mixing [541]. Interest in instrumental high performance preparative liquid chromatography is, of course, the result of the development of instrumental highperformance analytical liquid chromatography. This technique developed rapidly after 1970 thanks to the introduction ofreliablehighpressure pumps, efficient on-stream detectors, and the reintroduction of smaller, fully porous silica gel particles [542,543]. Chemical derivatization of silica gel stationary-phase particles also made modern instrumental liquid chromatography more reliable and accessible for both analytical and preparative applications [5441. For preparative separations, larger equipment, column, and packing materials are used. The goals ofpreparative HPLC aredifferent from those of analytical and trace analyses [545]. In preparative chromatography the aim is to isolate or purify compounds; in analytical work, the goal is to obtain information about the sample. Therefore, the importantparameters in analytical HPLC are resolution, sensitivity, and fast analysis time; for preparative HPLC the focus is on the degree of solute purity that can be achieved and the amount of compound that can be produced per unit of time, known as throughput. With good column technology, the sample sizeis linearly proportional to the column or stationary phase size. Thus, columns of increased sizeare
Liquid Chromatography
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used whenlarge samples are to be separated. It is not always easy, however, to achieve good column technology. Relative retention, or alphavalue, is the most important parameter in determining possible sample size.It is therefore essential to maximize this value, and time devotedto optimizing itwill always be well spent. A general relationship between alpha and sample size cannot be used because too many variablesare involved. However, three somewhat different approaches to theoretical understanding of HPLC separation in an overload mode can be recognized at this point, as represented by the treatments of Knox et al. [546], Eble et al. [5471, and Guiochon et al. [5481. These individualdescriptions of preparative HPLC mainly reflect varying degrees of simplification in the final treatment, rather than fundamental differences in approach or assumptions. As we progress from the Knox model to the Eble model to that of Guiochon, there is a transition from general predictions based on explicit algebraic relationships to numerical calculations that require an increasing amount of computer effort. Each model can be useful in creating a picture ofhow preparative HPLC works and in helping practical chromatographers developa preparative HPLC method. The model of Knox assumes the Langmuir isotherm, approximates band shape by “nested right triangles,’’and ignores mixed isotherm effects (changes in one band due to the presence of another, for multicomponent samples). Bandwidthis derived as a function of sample massand the smallsample column plate number No. This model also present the effect of sample volume on the bandwidth. In the optimization of this model no computer calculations are required and all relationships can bederived algebraically. Unfortunately few attempts are made to verify quantitative accuracy of the final prediction using experimental data and this model far has been usedfor approximate predictions of a general nature. Eble’s model assumes the Langmuir isotherm and takes into account mixed-isotherm effects. This model gives good results in the case of the separation of two component samples. The values of k,, N,,, (sample weight), and W, (column saturation capacity) are given by this model for each solute. The Guiochon’smodelisbased on a numerical solution ofmassbalance equations for mass overloaded HPLC. This model takes into account convex and concave isotherms as long as the isotherm is representable by a two-term expansion. Separation of the two-component sample is predictable given information on individual solute isotherms plus the plate number of the column for asmall sample.Considerableexperimental verification of the final computer model is given in the original paper of Guiochon [5481.
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In a more recent paper, Snyder [549] compared the prediction of the above mentioned models withthe experimental data obtained also by Snyder in a previous paper [547]. Several theoretical considerations must be analyzed and verified in the experimental conditions in which preparative liquid chromatographic separations are performed. The Knox [546] and Guiochon [548] models assume that a Langmuir isotherm can be approximated by a two-term expansion. When w,/w, (w,-mass in g of injected solute W,-column saturation capacity, equal to maximum sample-mass that the column can hold in mg) becomes large enough, this approximation is no longer valid. The general effect ofa continued increasein sample size results in dramatic modifications of the shape of the resulted chromatogram. The band tends to become narrower and taller for larger values of w,/w,. The results obtained by Snyder [549] suggests that the Knox and Guiochon modelswill beginto fail when WJW, approaches a value of 0.1. However the Knox model is surprisingly accurate in some respects, and simple enough to provide a picture of what will happen when certain changes in separation conditions are made; e.g., variation of k,,, a,N , and sample size. Its main limitations appear, to be (1) the neglect of blockage effects arisingfrom the presence of twoor more compoundsin the sample, and (2) its eventual failure as WJW, ”* 1. Predictions by the Knox model may therefore be significantly in error, particularly when we attempt to predict yield and purity as a function of sample sizefor overlapping bands. The Knox model also becomes more complicated to use for predictions when samples containing different proportions of two solutes and are of interest. Using a computer simulation program in which are incorporated two features of the Knox model (use of right triangle band shapes for larger sample size and the use of Knox relations for the calculations bandwidths), Snyder et al.[549] have shownthat this model can provide reliable predictions of the separation of sample mixturesthat contain two or more components. A major question in any preparativeHPLC separation is “what sample size is optimum for a given set of other conditions (column, mobile phase, etc)?” The Knox model has assumed that an optimum sample size corresponds to a value of w,/w, that gives R = 1. This is a useful first approximation, but most chromatographers intuitively believe that larger samplesizes are advantageous if the yield of purified product is to be maximized. Using a computer simulation, Snyder et al. [549] determined the optimal parameters for the chromatographic separations under overload conditions. Taking into account the blockage effects, the dependence between throughput sample size, k,, and column-packing particle size is determined. The conclusions includethe following:
Liquid Chromatography
I65
The weight of samplethat can be chargedto a column depends mainly on the separation factor a of the critical band-pair, and to a lesser extent on the plate number ofthe column for a small sample. A change in solvent strength and related solute k‘-values affects the optimum of N, for the separation, but has little effecton throughput (maximum quantity of purified solute per run) when k, (value of k‘ for a small sample) for the first band is between 0.5 and 1.5. Throughput decreases for larger k,-values (k, > 1.5 for the first band). Throughput can be increased in some(but not all cases) by charging larger samplesthan correspond to the case of two bands of interest just touching ( R , = 1). The effect of particle size on throughput iscomplex and there is currently no single “rule of thumb” to guide its choice. Because of this complexity, the optimum particle size for any given case can best be determined only from a knowledge of the exact circumstances surroundingthe separation.
E. Equipment Figs. 14 and 15 are a schematic of the instrumentation required for highperformance liquid chromatography and, respectively, a general view of a liquid chromatograph produced by Knauer company (Germany). The instrumentation comprises several components: A solvent reservoirthat contains the mobile phase A high pressure pump used to push the mobile phase through the tightly packed column A pressure gaugefor monitoring the pump pressure An injection device, usually containinga sample loop, used to introduce the sample into the moving mobile phase A column, typically tube a of stainless steel10 to 30 cm in length, 3 or 4 mm i.d., which has been tightly packed with small particles (10 pm) of the material usedto effect the separation A detector, frequently a variable wavelength UV spectrophotometer, used to measure the concentration of the sample components as they elute fromthe column A potentiometer recorderthat produces the chromatogram An optional data handling module to facilitate quantitative analysis and report writing The solvent reservoirfor HPLC is determined bythe type of pumping used (e.g., syringe pumps containa limited reservoirequal to the volume of the fullydisplacedpiston). Here the solventisdegassedexternally and
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Chapter
Figure 14 Schematic of HPLC instiumentation: 1, filter; 2, solvent reservoir; 3, pump; 4, pulse dampener;5, sample valve;6, guard column;7, column; 8, detector; 9, waste reservoir; 10, data system (optional);11, recorder.
i
Figure 15 General viewof a liquid chromatograph produced by Knauer Company (Germany).
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added to the pump chamber. However, other typesofpumps,suchas reciprocating piston types, containa separate solvent reservoir. Ideally,the reservoir must meet several requirements: Contain a volume adequate for repetitive analysis Provide solvent degassing either by heating or applying vacuum or allowing sparging with heliumand Be inert with respectto the solvent Frequently,glass or stainlesssteelcontainers of 0.5 to 2 Lmake suitable solvent reservoirs. Where space allows,the use of the glass bottle in which the solvents are purchased makes an excellent solvent reservoir. These should be carefully cappedto avoid contamination from the laboratory atmosphere. The solvent is the mobile phase; its purpose is to carry the sample through the column and produce a reasonable distribution (capacityfactor) between the mobile and stationary phases. The solvent must dissolve the sample. In addition the solvent must be of high purity, preferably HPLC quality. Other desirablefactors include low cost, low viscosity, low toxicity, and low boiling point. Depending the type of column employed, the solvent will vary. Table 16 illustrates the most commonly used solvents in liquid chromatography. One of the most important components in HPLC is the pumping system. By producing reproducible high pressures, the pump is a major factor in obtaining high resolution, high speed analyses, and reproducible quantitative analyses.The requirements ofa good pump include: A stable flow without pulsations to minimize detector noise A range of low rates for solvent delivery suitable for the various HPLC modes (usually0.5 to 10 mL/min) A constant volume delivery to facilitate qualitative and quantitative analysis A tolerancefor high pressure (6000 psi) and An easy adaptabilityto gradient operation
Table 16 Commonly Used HPLC Solvents
HPLC ~
NormalphaseHexane
or iso-octane, methylenechloride, chloroform, ethyl acetate Reversed phase Water, methanol, acetonitrile
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The pump with reciprocating piston utilizesa piston in direct contact with the solvent. The piston is driven either mechanically with motors and gears or by solid-state pulsing circuits. A simple versionof the reciprocating pistonpump is shownin Fig. 16 and Fig. 17. The last figure represents the analytical version of Knauer (Germany) HPLC pump Type A motor-driven piston moves rapidly back and forth in a hydraulic chamber. By means of check valves on the backward stroke, the piston sucks in solvent from a reservoir. At this time the outlet to the column is closed to preserve the operating pressure insidethe column. On theforward stroke the pump pushes solvent out to the column and the inlet from the reservoir is closed. eccentric cam drives the piston in three steps: (1) rapid reset; (2) rapid displacement until operating pressureis reached; and a smooth constant volume displacement to provide a uniform flow rate. This is an inexpensive pump that allows a wide range of flow rates. Unfortunately, it does produce flow pulses,and a pulse dampening system must be employed. One approach to eliminate pulsations is to use multihead pumping systems. Twoor three pumping assemblies offsetin time can produce essentially pulseless flow. Other models electronically sense the pressure between
2-
Figure 16 Schematic of reciprocating pistonpump: 1, column; 2, piston; reservoir;6, check values;7 , hydraulic chamber.
4, motor; 5 , external
cam;
Liquid Chromatography
I69
Figure 17 Analytical versionof Knauer HPLC pump type 64.
pump pulses and automatically change the speed of the stepping motors to minimize flow pulses. Gradient operation is achieved either by premixing the solvents at low pressureprior to pumping or by the addition of a second pump and mixing at operating pressures. The syringe pumps operate by a screw gear placing the plunger through the solvent reservoir. They are expensive, but usually produce stable flow rates and highpressures.This is sometimes overshadowed by the inconvenience of the several washings required when changing solvent systems. Syringe pumps are particularly well suited to gradient operation because each solvent is contained in separate reservoirs and the speed of each syringe plunger can be electronically controlled to produce the desired gradient. Of course, two syringe pumps must be usedfor gradient operation.
l . InjectionSystems Samples are introduced by one of three systems: (1) syringe injection; sample valve;and automated sample valves. Sample valvesare themost
I 70
Chapter
widely used because they providea more reproducible volume injectedand better quantitative analysis. They can be easily automated for unattended operation, andthey are not expensive. Syringe Injection. Low pressuresyringes for gas chromatography (GC) can be successfully used up to 1500 psi;however, precautions must be taken. At higher pressures, specially designed syringes are available. Requirements for septum materials are more rigorous in HPLC operation than in GC. The elastomer must have sufficient strength to enable successive needlepenetrations without total ruptureof polymer extrusion through the needle hole. This requirement is problematic with elastomers which swell in solvents. Generally, silicone polymers such as those used in GC are the most popular for LC systemsoperating with aqueous, aqueous-alcohol, or other polar mobile phases. However, with nonpolar organic solvents, swelling of the silicone elastomer precludestheir usage. Data are available from LC manufacturers concerning compatibility of elastomers with nonpolar solvents. Perfluoroelastomers are ideal with hydrocarbons and other nonpolar mobilephases.Septum material coveredwith a thin sheet of Teflon or otherinert polymer is also available. SampleValve. A fiied-volume loop isfilledwith the sample and, by turning a valve, this loop is placed into the solvent stream before the column. In Fig. 18, on the left,is a sample loop of stainless steelthat has been filled with sample from a syringe. For analytical work, the sample loop volume is usually 10 or 20 pL. Note that in this filling position the mobile
B
Figure HPLC sample valve. A, sample loading position. B, sample introduction position; 1, sample; 2, syringe; sample loop.
Liquid Chromatography
I71
phase at high pressure is passing directlythrough this sample valve to the column. On theright in Fig. 16, the valve has been rotated that the high pressure mobile phase now sweeps through the sample loop carrying the sample with it onto the column. This is a very reproducible techniqueand sample valves can be easily automated. Sample sizes can be changed by changing the sample loop volume. Unlike syringes, they do not suffer lack of repeatability due to operator variability or downtime due to septum deterioration. Sample valves must be constructed with minimum dead volumes and be of suitable materials to eliminate reaction between sampleor solvent. Some valves contain a large volume sample loop and allow “variable volume” injection by syringes. This isa convenience in method development, but it does not provide as good quantitative results as with fixed volume loops whichare completely filled with sample. The samplevalve approach hasbeen automated for unattended HPLC operation. In several versions, the sample is placed in small glass vials. The vials are indexed to a position where an excess volume of sample is pumped through a high pressure injection valve. The excess volume is necessary to thoroughly clean the sample loop. The sample is automatically injected and the sampler indexed to a new vial. Microprocessors can be used to repeat the injection of the same sample,to rinse the sample loop and connecting tubing between each sample,or simply to inject in sequencethe samples as loaded in the sampler tray.
AutomatedSample Valves.
2. Column Oven Many HPLC separations can be performed at ambient temperatures without the aid of a column oven. However, elevated temperatures are useful either to reduce retention volumesor to decrease the mobile phase viscosity and thereby increase the column efficiency. Lower mobile phase viscosity also enablesoperation at lower pumping pressuresor high flow ratesat the same pumping pressure. Three approaches are currently used in temperature control: (1) an external heat exchanger enclosingthe column through which water from a thermostatically controlled waterbath is circulated;(2) submerging the column ina water bath; using a hot air circulation oven as inGC. Useful temperature rangesare from 30 to 15OOC. Recent work has emphasizedthe change in column selectively caused by changes intemperature (see Table 17)[550]. This istrue even for adsorbents suchas silica gel. Thermostats were always required for ion exchange, gelpermeation, and liquid partition chromatography;theynow appear highly advantageous even for adsorption and bonded phase chromatography.
172
Chapter
Table 17 Effect of Column Temperature
Temperature ("C) 25 50 75
Platedm R 2.4
11,m 12,400 12,500
1.20 1.14 1.11
Source: Ref. 550.
3. Columns Columns for HPLC vary depending primarily on the type of separation desired and the physical characteristics ofthe packing materials. The most popular column length ranges from 10 to cm. Analytical columns have internaldiametersof 3 or 4 mm and are precision-borestainlesssteel. Column packings of small diameters(3 and 5 pm) use shorter columns (10 to 15 cm) due to the higher efficiency and larger pressure drops. The column packing is usually retained by inserting nickel or stainless steel frits into the fittings at the end of the column. The frit is effective in reducing dead volumeas well as producing uniform flow profiles. Columns for preparative separations are usually wider. Preparative scale columns have internal diameters ranging from 1 to 10 cm. They are useful for l-mg to l-g quantities of sample. Larger flow rates are required and most often automatic sample collectors are used in preparative scale work. Microbore columns are l-mm i.d. A 50-pL flow rate would correspond to 1mL/minwith normal analyticalcolumns.Thesesmallflow rates show increased sensitivity if the same sample size is applied to both microbore and analytical columns. Microbore columns with their very small flow rates have a definite advantage where expensive or exotic solventsare used. In addition, they provide a good interface for LC/MS, LC/FTIR, and LC/NMR. They do not, however, show any better resolution or faster analysis than regular analytical columns because chromatographic parameters do not depend on column diameter.
4.
Detectors
Although time has singled out some HPLC detectors as preferred devices for quantitation in the majority of separations, there is still a need for more sensitiveand selective detectors. Present research concentrateson the improvement of existing detection technology to perform more sensitive
Liquid Chromatography
I73
measurements, and onthe development of novel devices that impart greater selectivity or specificity. Detectors have been classified according to the principle ofoperation by which solutesare monitored selectively. Although the majority of detectors fall under the broad classification of spectroscopic or electrochemical techniques, due regard has been given to the expanding field of research concerned with postcolumn reactors based on immobilized reagents. The purposes of the detector are to measure the sample concentration in the mobile phase to produce an electrical signal proportional to the sample concentration. Detectors operating on the principle of monitoring ultraviolet (UV) absorption at a specific wavelength stilldominate HPLC as the most widely used detector type. The basic design has changed little in recent years, and the regular replacement of UV sources still represents the major maintenance consideration. Shown schematically in Fig. 19 is a simple fixed wavelength doublebeam UV photometer. On the left is the source, a low pressure mercury lamp that emits a sharp (essentially monochromatic) line spectrum with a strong line at nm. A quartz lens focuses the UV radiation on the sample and reference cells. The sample cell usuallycontains about 10 to 20 pL of the continuously flowing column effluent.The reference cell is usually filled with air. A UV filter removes unwanted radiation. The radiation passing through the reference and sample cells fallson two photodetectors. The output of these two detectors are passed through a preamplifier to a log comparator that produces the electric signal for the recorder. The log comparator is necessaryto convert the photons measured at the photodetector (transmittance) into absorbance units that are directly proportional to concentration.
a
Figure 19 Schematic of UV photometer, 254 nm; 1, mercury source 254 nm; 2, UV filter; mask; 4, sample cell; 5, electronics; 6, photodetector; 7 , reference cell; 8, quartz lens.
Chapter3
I74
The UV detector is inexpensive, sensitive, insensitive to normal flow and temperature fluctuations, and well suited to gradient elution. It is, however, a selective detector. Only sample moleculesthat absorb at254 nm can be detected. It cannotbe used for lipids, hydrocarbons, most polymers and oligomers, carbohydrates, and fattyacids. Because many compounds do not absorb at 254 nm, a variety of W / v i s detectors offering other wavelengths have become available. With the medium pressure mercury lamp and appropriate filters, wavelengths available include254,280,312,365,436, and 546 nm [551]. Spectrophotometers adapted for HPLC arepreferably the most common HPLC detectors today. Some are true recording spectrophotometers that allow a UV/vis spectrumto be generatedon an eluting peaktrapped in the flow cell. Others have onlymanual selection of wavelength (usually200 to 800 nm). This allows selection ofa wavelength to maximize sensitivityor minimize interferences, but does not allow a spectrum to be recorded. Figure 20 shows a schematic spectrophotometer used as an HPLC detector. This instrument uses a grating, thus allowing selection of any wavelength from 200 to 800 Light from a continuous source is focused on the entrance slit of a grating monochromater. By the appropriateoptics, this “white light” is focused on the grating where it is dispersed into the various wavelengths. By varying the position of the grating, the desired wavelength is focused on the exit slit and then passed through sample and referencecells by means of a beam splitter. The detector measures the
nm.
9 Figure 20 Schematic of spectrophotometerfor HPLC detector; 1, source; 2, grating; 3, exit slit;4, entrance slit;5, monochromator;6, beam splitter;7, reference cell; 8, detector; 9, sample cell; 10, rotating chopper.
Liquid Chromatography
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difference in lightintensity passing between sampleand reference cells. The detector signal is converted into absorbance by a logarithmic comparator. Spectrophotometers allow the selection of any useful wavelength in the UV and visible regions. The primary benefit is the increased sensitivity for the compounds of interest. Many compounds would not absorbwell at 254 nm, and thereforegreater sensitivity is possible with a spectrophotometer. In some cases, noise or interference from the sample matrix is also reduced by usinga spectrophotometer. UV detection in capillary liquid chromatography has been studied to determine the relationship betweenmaximumachievablesensitivity and minimum extracolumn dispersion. There is an apparent trade-off between best sensitivity and minimum dispersion, which is achieved through oncolumn detection. Diode array detection (DAD), as an extension of conventional UV absorption detection, has found wide application in HPLC method development for peak identification and tracking. Although the optical hardware hasnot changed significantly,software development revealsthat there is a lot of ongoing research. Information retrieval and processing is a very important aspect that has contributed to anincreasing range ofDAD applications. few manufacturers of liquid chromatographic detection equipment have introduced low cost devices that monitor a limited number of wavelengths by rapid scanning and offer some of the facilities available on the DAD systems. These instruments allow the entire UV/vis spectra to be recorded rapidly and stored digitally in a microprocessor where it can be recalled or handled in several ways. large number of detector elements (32 to 512 inpresent designs)can store and read out theimpinging radiation in milliseconds. Major uses include peak identification by having a UV/vis spectra for each liquidchromatographic peak, determination of peakpurity by absorbance ratioing at two wavelengths, and multiple chromatographic recordings at avariety of wavelength,that can be displayed after the runto maximize sensitivityor minimize interferences. Limitations of the photoiodide array detector include the high cost (15,OOO-25,000 USD), depending on the microprocessor capability, limited linear range ofthe present diode arrays, and, finally, limited signal/noise primarily due to both optical and electrical noise. Keller and Massart [552] described a method for peak purity control based on evolving factor analysis. The factor analysis is performed on a moving window with a fiied, rather than increasing, number of spectra. Impurities with similar spectra to the analyte could be detected below19'0. Bunger et al. [553] applied the Meister method of curve resolution to resolve overlapping peaks of complex hydrocarbon mixtures. The specific resolution of polyaromatic hydrocarbons was found to depend on thenum-
I76
Chapter 3
ber of principal components used in the curve resolution method. Results wereshown for up to five principal components. A novel approach to enhance peak recognition has combined postcolumn continuous-flow analysis with DAD [554-5561. Fell et al. [557] described further work where KOH solution is addedto the carrier stream to generate pH-shifted differa ence spectra. There were obtained a number of dipeptides containing tyrosyl residue by subtractingthe normalized spectrum under alkaline conditions (pH 12.4) from the spectrum obtained at pH 4.4 (reversed phase conditions). Strasters et al. [558] reviewedthreemultivariatetechniques (multicomponent analysis, targetfactor analysis, and iterative target transformation-factor analysis) for peak deconvolutionas a means ofautomated peak recognition for computer-guided strategies in HPLC. They conclude that the final result of the optimization is substantially dependent upon the technique selected and spectral information. Fell and Berridge [559-561 J have applied the multichannel detection capability of DAD to assist automated optimization strategiesin HPLC. Verzele et al. [562] reported procedures to enable commercial DAD systems to be adapted for microliquid chromatography. A piece of fusedsilica capillary, stripped of polyimide coating, was mounted in a detector block. The paper discussed the control of a number of parameters that affectdetectorperformance,includingrefractiveindexchanges,optical dispersion, and optical alignment. Refractive index is a universal detectorthat will respond to all sample types. It is more expensivethan the simple UV detector, but less expensive than a spectrophotometer. It requires very goodtemperature and good flow control, and is not amenable to gradient elution. Sensitivity is limited to about 1 pg of sample. The refractive index (RI) detector is useful in gel permeationchromatographywork,preparativeseparations, and routine quality control where trace analysis or gradient elution is not required. It is usually neither sensitive nor stable enough for routine analytical work
5. Fluorescence Conventional fluorescence has been applied for highly selective and sensitive detection ofboth naturally fluorescent analytesand analytes that have been derivatized. The proportional response of fluorescent emission intensity to exitation intensity has inevitably led to the development of laserinduced fluorescence(LIF). Modern lasers are more robust and stable and offer an increasing selection of emission wavelength. Two complementary reviews on LIF are reported. One discusses the development of LIF, its advantages over conventional fluorescence detec-
Liquid Chromatography
I77
tion, and the use of different flow cell designs The other places an emphasis on trace bioanalysis of drugs, with a focus on techniques such as frequency doubling, variable wavelength dye lasers, and derivatization procedures The detection of glucuronic acid conjugatesafter derivatization with the fluorescein fluorophore was reported A LIF system constructed around a continuous-wave argon-ion laser enabled a limit of detection of ca. mol.Thisrepresentsagain in sensitivityoverconventional fluorescence detection ofan order of magnitude greater than 4. Gooijer et al. applied LIF toconventional HPLC of a standard mixture of polyaromatic hydrocarbons.A frequency-doubled argon-ion laser was used to excite at nm. Short-wavelength excitation reduced Raman scattering of the eluent, which can interfere with analyte fluorescent emission, while increasingthe application of LIF to a wider range of analytes. Improvements in limits of detection of 4 to times were reported, with further improvements limited by background luminiscence ofthe solvents and quartz cell walls. Further work by Gooijer reported the addition of an intensified linear diode array (ILDA) detector to their frequency-doubled LIF. This enabled identification through real-time monitoring of the fluorescence emission spectrum. Delorme developed a dual-mode laser-based detection system for HPLC. LIFwas combined with thermal lensing spectroscopy in a single flow cuvette.The detection of separated NDand U was reported. Fell et al. examined conventional fluorescence detection with an ILDA detector for its potentialcontribution in pharmaceutical and biomedical analysis. The data were presented as an isomeric plot (emission intensity, emission wavelength, time)and techniques to assess peak homogeneity were applied. Goijer et al. described a detection systemfor liquid chromatography based on the measurement of long-lived luminiscence in an attempt to discriminateagainstshort-livedbackgroundfluorescence. A pulsed Xe lamp and a gated photomultiplier were used.The lanthanide ion Tb(II1) was used as a luminophoric label with thiol-containing analytes. Luminescence sensitizationand derivatization through the thiol functionality were achieved in the reagent 4-maleimidylsalicilic acid. 6. Chemiluminescence
The sensitivity of fluorescence detection is frequently limited by the presence of impurities that give rise to interfering luminescence background signals. Oneapproach to overcome this problemis to applychemical, rather than spectroscopic, excitation. Chemiluminescence involves postcol-
I78
Chapter
umn reaction with the HPLC eluent and collection of emitted light at a specific wavelength. In a comprehensive review,Jong and Kwakman [574] address recent developments in the chemiluminescence detection of biomedicalsamplesseparated byHPLC.Details arediscussedonperoxyoxalate, luminol, and lucigenin based chemiluminescence, as well as a brief account of bioluminescence reactions. Kwakman et al. [575] described peroxyoxalate chemiluminescence detection of primary aminesafter precolumn derivatization with naphthalene2,3-dialdehyde (NDA), or anthracene-2,3-dialdehyde(ADA). A modified commercial fluorescence detector with excitation source turned off was utilized to obtain enhancement in limits of detection of25 and 50 times for NDA and ADA derivatives, respectively. ADA derivatives suffered from rapid decomposition, especially in the presence of hydrogen peroxide. Although LIF could give further improvements in detection limit enhancement, the chemiluminescence technique was considered preferable, due to its lowcost,asameans gainingsuperiorsensitivitytoconventional fluorescence detection. Jones et al. [576] described a similar chemiluminescence detection system based on a commercial fluorescence detector with the excitation lamp shutter in the closed position. A postcolumn reagent based on luminol was usedto detect cobalt at picogram levels after separation on a cation-exchange column.
7. OpticalActivity Polarimetric measurement of optical activity and the related technique of circular dichroism have played increasingly important roles as HPLC detectors. Chiral phases for the separation of enantiomers coupled to detectors that exploit the measurement of optical activity provide an important and growing research field within HPLC technology. Lloyd and Goodall have recently reviewed polarimetric detection in HPLC [577], with an emphasis on the selective detection of optically active molecules. Meihard and Bruneau [578] employed tandem UV absorptionpolarimetric detection in studies to develop a chiral phase that would resolve the deltamethrin racemate. The UV detector gave the sum of the signals due to the two optical antipodes and thepolarimeter the difference. These data were usedto quantify the two optical antipodesin a mixture and assist in the development of a new HPLC chiral support. Goodall et al. 15791 applied a dual optical rotation-UV absorbance detector system for the determination of the enantiomeric purity of ephedrine and pseudoephedrine separatedby HPLC. Goodall et al. [580] described the construction and application of a diode-laser-based optical rotation detector. The detector components are
Liquid Chromatography
I79
summarized in Fig. 21. A collimated laser diode source emitting at 820 nm was focused onto an HPLC flow cell ( 8 pL) via a polarizer. A Faraday effect modulator oscillating at 1.45 kHz was arranged to give a modulation angle of up to 1 The cell beam, after passing an analyzer (similar to the polarizer) was detected by a silicon photodiode. Due to the inherently low flicker noise characteristics of diode lasers, the design could be simplified. The determination of D- and L-tryptophan mixtureswas demonstrated. A circular dichroismdetector, with simultaneous measurement of absorbance, was usedto evaluate the anisotropy factor andhence the enantiometric excess of the eluates [581]. This approach was applied to preparative chiral HPLC to enable optimized collectionof enantiomeric fractions.
8. AtomicSpectroscopy Element-specific detection in liquid chromatography still accounts for only a small proportion of detection principles employed. The perceived complexity of atomic spectroscopic techniques and the challenges presented in the interface design have prevented the development of commercial detectors based on atomic spectroscopy. However, the inherent benefits of element-specific detectionare demonstrated for the analysis of trace organics in complex samples. Furthermore, effort continues in the research associated with linking liquid chromatography to atomic spectroscopic systems for specialized applications. Kientz et al. [582,583] have designed and evaluated an interface for the on-line coupling of microcolumn liquid chromatography with a flame photometric (FPD) detector. In this work, a commercially available FPD designed for gas chromatography was modified to permit direct introduca
b
c
d
e
f
Q
00 Iu Figure 21 Schematic diagram to show construction of the optical rotation detector. (a) diodelasersource; (b) collimaticlens; (c) polarizer; (d) calibrator; (e) Faraday effect modulator; (f) LC flow-cell; (g) Glan-Taylorprismanalyzer; (h) photodiode detector;(i) DC supply; (j) audiofrequency power amplifier;(k) lock-in amplifier.
l80
Chapter
air
b
C
t hydrogen
d helium
Figure 22 Schematic diagram of LC flame photometric detector. (a) Burner assembly, (b) stainless steel tube (0.50 mm i.d.), (c) fused-silica capillary (0.32 mm i.d.), (d) fused-silica capillary interface (0.10 mm i.d.). tion ofthe column effluentinto a hydrogen-air flame. A simple design (Fig. 22) in which a fused-silica capillary (0.1 mm i.d.) is inserted into the base of the flame was assessed accordingto a number of operating parameters. The position of the capillary, gas flow rates, and quenching effects of the eluent were considered, and the detection a number of organophospho20 pg rus compounds was demonstrated. A detection limit of phosphorus per second was claimed. Graphite furnace atomic absorption spectroscopy (GFAAS) has the advantage of high sensitivityand selectivity for small sample volumes.The discontinuous nature GFAAS sampling presents an obvious disadvantage. Astruc et al. [584] investigated the theoretical limits of GFAAS as a discontinuous detection procedurefor liquid chromatography. Their theory shows that optimum detection may be achieved when the liquid chromatographic peak width is the same order of magnitude as the cycle time of the GFAAS. Their theory was verified by the speciation of butyltin compounds at sub-mg/L concentrations. Haswell et al. [585] applied reversed phase HPLC interfaced to electrothermal atomization atomic absorption spectrometric detection.The specificity ofthe detection system toward cad-
Liquid Chromatography
181
miumwasused to monitor the separation and speciation of cadmiummetallothionein type complexes.
9. Mass SpectrometricDetectors It is beyond the scope of this chapter to review the rapidly increasing applications of liquidchromatography-massspectrometry(LC-MS). It is important, however, to highlight a few significant developments that have demonstrated novelty in the interface-ionization mechanism. It is the technology by which liquid chromatography is coupled to mass spectrometry that ultimately limitsthe performance and application of LC-MS as a sensitive and selective LC-detectorcombination [586,587]. Dynamic fast atom bombardment(FAB)LC-MS,which can give molecularweight information and structure-characteristic fragmentation data, has been associated mainly with low-resolution MS. Kostianen et al. [588] demonstrated LC-MS usinga frit-FAB interface coupled to a high-resolution MS. This was applied to the identification of several trichothecenes. The reversedphase separation consisted of a methanol-water gradient witha postcolumn addition of glycerol. Polyethylene glycol was added as a calibrant for an MS scan range m/z 150 to 500, with resolution of8000. An alternative to the frit-FAB interface is the continuous-flow FAB (CF-FAB), that is basedon setting up a film on a nickel, silver,or stainlesssteel target. Niessen et al.[589]studiedsomeof the important factors affecting the performance of a CF-FAB interface based on a target fed from a fused-silica capillary (Fig. A range of conditions were studied for the fourtarget materials, with the conclusion that thewettability of the target was a key factor in determining stable operation of the FAB intera
Figure 23 Schematic diagram of a continuous-flow FAB-MS probe interface.(a) LC-capillary, (b) FABtarget,(c)compressedpaperwick, (d) exchangeable ion volume, (e) homogeneous film of LC mobile phase on target surface.
I82
Chapter 3
face. The effect of glycerol concentration in the mobile phase was also investigated, with optimum performance obtained with 7% (w/w) of glycerol, representing a supply rate of 0.3 pL/min. Pullen et al. [ 5901 described the design and construction of a microcolumn LC-MS interface based on corona discharge ionization. The system was designed for the detection of known target compounds at trace levels in pharmaceutical formulations and biological fluids. High sensitivity and minimum sample workup were essential prerequisites. The ionization chamber was based on a precisely controlled point-to-point discharge that enabled successful focusing on the region of maximum ion generation with the ion slit and quadrupole analyzer. Stenhagen and Alborn [591] have utilized an electron input ion source that permits direct connection with microcolumn liquid chromatograph based on a packed fused-silica column (0.22 mm i.d.). The nebulization of the eluent was controlled by the electrostatic field set up between the column end and an extraction-focusing plate. The main advantage claimed for this interface arrangement was reduced thermal decomposition of labile compounds. Operation of the interface was demonstrated for a number of separated plant allelochemicals. Speciation of tributylin in water samples was presented by Ebdon et al. [ 5921 who demonstrated HPLC coupled to inductively coupled plasmamass spectrometry (ICP-MS). With a standard ICP torch, a limit of detection of 25 ng/mL was achieved.
10. Electrochemical Detectors Electrochemical methods of detection in HPLC have failed to achieve widespread popularity. For a number of applications, the selectivity of electrochemical measurements has ensured their adoption over detectors employing other measurement principles. The complexity of operation of some electrochemical detectors and the need for regular maintenance of electrodes and flow cells are possible reasons for their confinement to special applications. The conductivity detector has been successful when applied to ion-chromatography monitoring followed by the pulsed amperometric detector that maintains electrode surface integrity through electrochemical cleaning. The potential for the application of electrochemical measurement systems to HPLC detection is increasing due to research in the areas of flow-cell design, new electrode materials, and advances in the associated instrumentation. In a recent review, Buchberger [593] highlighted advances in the coupling of electrochemical detectors with HPLC. Voltametric detectors were emphasized, with discussion of new electrode materials, new excitation functions, and new application resulting from these developments [ 594-5961.
Liquid Chromatography
I83
A convenient means of classifying electrochemical methods of detection is to distinguish between principles of operation, grouping detectors that use equilibrium as opposed to dynamic processes. Detection systems that do not promote oxidation or reduction of the analyte are termed “equilibrium,” whereas all other systems that involve electron transfer (amperometric, voltametric, and coulometric) may be termed “dynamic.”
Equilibrium Electrochemical Detection. A novel detector for simultaneous conductivity and pH measurement was described by Slais [597]. The cell volume, estimated at 150 nL, was suitable for detection of microcolumn liquid chromatographic effluent. Measurement of the pH, based on an antimony microelectrode, enabled the detection of changes as low as f 0.004 pH. A miniaturized lead-lead sulfate reference electrode was used to avoid noble metal contamination of the antimony surface and any consequent degradation in the performance of pH measurement. Conductivity, with a sensitivity of f 50 ns/cm, was detected between the antimony microelectrode and a third auxiliary electrode constructed from a stainless-steel capillary. Slais and Janecek [ 5981 reported a simultaneous photometric and conductivity detector in an earlier paper. This detection system, also designed for microcolumn liquid chromatography, claimed a volume of 100 nL with an optical path length of 1 mm. Optical fibers were used as an optical link between the flow cell, UV source, and photomultiplier. Examples of indirect UV-conductivity detection of separated anions and carboxylic acids were presented. Slais and Oscik-Mendyk [ 5991 demonstrated the application of a simultaneous conductivity and amperometric detector for the determination of dicarboxylic acids separated by microcolumn liquid chromatography. The detector, based on a manganin working electrode, has a reported cell volume of 20 nL. Electrokinetic detection is based on the measurement of the streaming current generated by the movement of a liquid along a solid surface. This phenomenon can be exploited for the measurement of liquid chromatographic effluent composition. The streaming current arises from the fact that part of the spatial charge of the electric double layer is carried by the streaming liquid. In practice, the charge carried may be measured by an isolated collector electrode. The generation of a streaming current, I,, is described by the Helmholtz-Smoluchovsky equation, where
r, = A
~ P
( 106)
A is a constant dependent upon the composition of the streaming liquid
and measurement cell geometry, P is the pressure gradient on the streaming current generation cell, and is the zeta potential, which defines the edge of the outer Helholtz layer. For a capillary, the zeta potential is given by:
184
Chapter
where 11 is the viscous force per unit area, 4 is the volume flow per unit time, q is the capillary cross-sectional area, e, is the permittivity of free space, and e is the relative permittivity of the streaming liquid, such that is also a function of column effluent composition. Vespalec and Neca [600,601] have exploitedthis electrochemical phenomenon for liquid chromatographic detection. They studied the effect of detector construction with respectto the magnitude and polarity of streaming currents for both normal and reversed phase separation modes. Detection limits for several nitrophenols were achieved in the range 10-9-10”1 mol. A detection limit of1.8 molwasclaimed for dipicrylaminein a mobile phase ofn-heptane-acetone 10) with10 ppm of nitric acid. Dynamic Electrochemical Detection. Amperometric detection is the most
widely used example of dynamic electrochemical measurement for liquid chromatography detection. Gratzfeld-Huesgen and Haccker[602]discussed the optimization ofsensitivity through selection of appropriate working potentials in thin-layer cell amterometric detectors for HPLC. The stability of operation is also discussed, with reference to electrochemical cleaning to promote electrode life. The cell designis very important to the operation voltametric detectors. Wall-jet geometries can offer considerable advantages over thin film electrodes both in terms of simplicity of construction and in terms of reduced band broadening. Horvai et al. [603] studied band broadening in large volume wall-jetcells used for electrochemical detection inliquid chromatography. The necessity for smooth flow patterns and the conditions that promote stable operationwere discussed. Nagels etal. [604] investigated large volume wall-jetdetectors and studied rapid-scan staircase voltammetry under convection-diffusion and diffusion-controlled conditions. The importance of the parameters of flow rate, electrode diameter, and scan rate was demonstrated for microbore and microliquid chromatography as well asfor conventional liquid chromatographic conditions. Electrode materials. New electrode materials and chemically modified electrodes continue to be reported for applications in electrochemical measurements.Amperometric detection hasbeenused in conjunction with some novel electrode types and with electrodes that have chemically modified to impart selectivity or improve performance. Hart et al. [605] demonstrated the determination glutathione in human plasma samples using HPLC coupled amperometric detection. A carbon-epoxy resin composite working electrode, which has been chemi-
Liquid Chromatography
185
cally modified withcobalt phthalocyanine, was reported. The cobalt phthalocyanine actedas an electrone mediator to assist the kinetics of the electron transfer process of glutathione electro-oxidation. A detection limit of 55 ng/mL for glutathione was claimed. Nagels et al. [606] and Schuddinck et al. [607] reported a novel carbon-polymer chip electrode for microliquid chromatography detection. The working electrode was constructed from 20% (w/w) carbon-loaded ethylene-vinyl actetate copolymer (containing 9% vinyl acetate) that was bonded around two polyamide-coated fusedsilica quartz capillaries (100-pm i.d.). A stainless-steel wire, previously inserted into the spaced capillaries, was withdrawn after two polymer chips were compressed on a hot plate to form a conducting tubular electrode between the fused-silica capillaries. The detection of catecholamines, separated by microliquid chromatography after solid phase extraction from urine samples, was demonstrated. Stulik et al. [608] utilized a passivated copper electrode for selective amperometric detection of ethylenethiourea in beverage samples separated by HPLC. The selectivity was attributed to the complex reaction between ethylene thiourea and copper I1 ions. A detection limit of 3 ng/mL was reported for a200 pL injection volume. Smythet al. [609]compared amperometric detectionemploying a static mercury drop electrode (SMDE) with a glassy carbon working electrode for the determination of cisplatin following HPLC separation. A detection limit of 5 pg/mL for the SMDE compared with ng/mL for the glassy carbon was reported. It was found, however, that regular polishing was required for the glassy carbon electrode to maintain performance. alternative cell arrangement, where a dual-in-parallel amperometric detection mode was employed, enabled a decrease in the detection limit to 25 ng/mL, due to enhanced signal-to-noiseconditions.
Electrode Arrays. Electrode arrays, where a numberofindependently controllable working electrodesmonitor HPLC effluent either seriallyor in parallel, could be to electrochemical liquidchromatographic detectors what the diode array spectrometer is to UV absorbtion detection. To date, the only commercially available electrochemical array detector is based on serial measurementofliquid chromatographic effluent through interconnected coulometric cell compartments. Onlyrecentlyhave the potential applications of such a detection system been explored. Rizzo et al. [610] reported the determination of neurochemicals in biological fluids using a 16-electrode coulometric array detector. Of molecules searched for, 21 could be measured after direct injection of a plasma sample,illustrating the potential selectivity of electrode array detectors. An alternative to the costly and complex arrangement required for
Chapter
186
coulometric arrays is to control a single cell comprisingan array of miniature disk working electrodesand anassociated auxiliaryand reference pair. Fielden et al. [61 l ] demonstrated preliminary results ofan array of miniature electrodes mounted ina single plane.A wall-jet cell geometry was used to minimize band broadening (Fig. 24) and maintain a rapid response. The electrochemical detection of a mixture of phenols was reported with simultaneous monitoring of eight different oxidation potentials.
1 l . Postcolumn Electrochemical Derivatization A few specific examples of electrochemical reagent generationfor postcolumn derivatization have been reported. Many examples of enzyme reactors linked to amperometric detection have also been described (see postcolumn reactors, following). Electrochemical generation of reagents can potentially be finely controlled with microcell volume compatibility. Mascher and Kikuta [612] describe an HPLC separation couple to a fluorescence detector via a coulometric cell. The determination of amoxicilin was studied with electrochemical postcolumn oxidation of the separated analyte leadingto the formation of a fluorescent byproduct.An absolute detection limit of 10 pg injected was claimedfor the direct injection of plasma samples without prior treatment. Palmisano et al.[613 J utilized a postcolumn coulometric cellto gener-
e
C
Figure 24 Schematic diagramto show constructionof the wall-jet electrode array for LC-voltametric detection. (A) Section through the cell: (a) platinum auxilliary electrode, (b) electrode array assembly, (c) working electrode cell half, (d) O-ring seal, (e) outlet, (f) maincellbody, (g) inlet jet (0.3 mm i.d.), (h) silver-silver chloride reference electrode with sintered glass junction. (B) Close-up of working (1 electrode array, comprisedof high-regularly spaced glassy carbon-disk electrodes mm diameter).
Liquid Chromatography
187
ate bromine on-line. The microtoxins altenuene and isoaltennene were derivatized by the electrochemically generated bromine after reversed phase liquid chromatographic separation. A detection limit of 8 ng on column was reported. Malcolme-Lawes etal. [614] describeda computer-controlled electrochemiluminiscence monitor for liquid chromatography. The chemiluminiscence intensity could becontrolled by electrochemical parameters, such that computer-optimized chemiluminiscencewas realized.
7 2 . Detection by immobilized Enzyme Reactors A survey ofpostcolumn reaction technology has been included in this chapter, as column reactors have become more widely used for enhanced selectivity in the detection process for liquid chromatography. It is convenient to classify such column reactors as those based on enzymes and those that empldy other reagent chemistries. Marko-Varga et al. [615,616] have comprehensively reviewedthe application of immobilized enzyme reactors for selective detection in liquid chromatography. The incorporation of immobilized enzyme in liquidchromatographic systems, selectivity toward interferences, and many examples are discussed. An emphasis is place on systems that combine immobilized enzyme reactors with electrochemicaldetection, particularly amperometric detection. The application of chemically modified electrodes to this task is also surveyed. Tagliaro et al. [617-6191 reported the development of postcolumn immobilized enzyme reactors based on alcohol oxidase. Details of the immobilization procedure were given, witha consideration of band spreading due to reactor void volume. The reaction product, hydrogen peroxide, was monitored amperometrically at a platinum working electrode polarized to +500 mVvs.Ag-AgC1. Detection limits of 2.5 nmol and 0.6 nmol for ethanol and methanol, respectively, were determined. Marko-Varga [620] has utilized two serial immobilized enzyme reactors for the determination of mono- and oligosaccharides in fermentation broths afterliquid chromatographic separation. The detection principle was based on a sequence of enzymatic reactions. Free glucose monomers were first generated bythe hydrolysis of poly-and oligoglucans due to amyloglucosidase (AMG) maltodextrins
AMG
+
P-D-glucose ( at-D-glucose)
(108)
This step was followedby reactions with glucose dehydrogenase(GDH),
Chapter
188
NAD+
+ 0-D-glucose + H ~ O% + H+ + NADH
D-gluconate
(109)
that resulted inthe oxidation ofthe 0-D-glucose. Mutarotase was added to the second reactor column to transform the a-D-glucose formed in the first step to the 0-anomeric form. A phenoxazine-modified electrode was used in an amperometric detector to monitor the NADH produced by the second reactor column. Variations on this approach werealsoreported for the enzymatic production and analysis of D-xylulose [621] and the determination of sugars in spent sulfite liquor [622]. Marko-Varga et al. [623] reported stereoselective detection ofL- and D-amino acids using a postcolumn immobilized enzyme reactor containing either L-or D-amino acid oxidase. A second reactor containing immobilized horseradish peroxidase was used to promote the formation of a red-colored complex bythe reaction of hydrogen peroxide generated the by first reactor with 4-aminophenazoneand dichloropheno-sulfonyl chloride. Townshend and Leon-Gonzales [624] employedthe inhibition of immobilized acetylcholinesterase to selectively detect organophosphorus and carbamate pesticides separated by liquid chromatography. a-Naphthyl acetate was hydrolyzed by the immobilized enzyme to an a-naphthol, which was reacted withp-nitrobenzene-diazonium fluoroborate to give a continuous absorbance at 50 nm. Inhibition of the cholinesterase ledto a decrease in baseline absorbance. An extensive review of Brinkman et al. [625] considered the design, construction, and application of postcolumn reactors. This included discussion on open-tubular,packed-bed,segmented-stream, and hollow-fiber membrane reactors. Irth et al. [626] describeda postcolumn ligand exchange reactor coupled to selectivespectrophotometricdetection for the determinationof PbII, CdII, and BiIIIseparatedastheirdiethyldithiocarbamate (DTC) complexes by reversed phase liquid chromatography. Ligand exchange with copper(I1) phosphate led to selective detection of Cu(DTC), at 435 nm. In a subsequent paper, Irth et al. [627] applieda postcolumn ligand-exchange reaction for the selectivedetectionofD-myo-1,2,6-inositol triphosphate (1,2,6-IP,). A reagentstreamof the Fe(II1)-methylcalceinblue(MCB) complex, which is weakly fluorescent, gave a low fluorescent background. Strongly fluorescent MCB, released the by ligand-exchange reaction, gave a detection limitof 3-10 ng of 1,2,6-IP3.
13. Recorders Standard strip chart recorders (1 and 10mV)such as are used in GC are also employed in HPLC. Chart speeds should be reproducible that
Liquid Chromatography
189
retention times (chart distance) can be used to identify peaks. Quantitative analysis is performed as in GC (i.e., peak areas or peak heights are measured and compared with standards). Disc integrators, electronic integrators, and computers are also usedto measure peak areas.
14. Data Systems Data systems are divided into two classes; the microprocessor-based electronic integrator and the computer workstation (Fig. 25). Electronic integrators are relatively easy to use requiring little or no setup. Most provide default settings that can be used for typical analyses. Electronicintegrators are limited in that they employ hardware programs that may not be suited for a given analysis, theydo not provide for storage or archiving ofchromatograms, and most cannot redo a chromatogram using different integration parameters without repeating the entire analysis.
Figure 25 Eurochrom software/hardware data system and monitor chamber HPLC system (Knauer Company, Germany).
a dual-
190
Chapter3
Although costing morethan electronic integrators, computer workstations provide more flexibilityand power. Mostcomputer workstations provide means for finer control over integration functions as well as archiving chromatograms, redrawing base lines, and aiding in data analysis and report generation. Disadvantages of computer data stations are their complexity, longer setup times, a lack of mobility, and higher initial cost than electronic integrators. As the electronic integrators gain both features and power and computer workstations become more user friendly, the line separating these classes of data systems becomes less distinct. The type of system neededcan only be determined by carefully evaluating whatisavailable (hardware and software) and matching the features available with the needs of the analysis.
75. Factors in Choosing HPLC Instrumentation Several major factors must be considered when purchasing an HPLC system. There are usually, in addition, several factors unique to each laboratory. The comments concerning each factor are the subjective opinion of the author. It is essential to knowif HPLC will solve the analytical problem. Fortunately, most manufacturers have well-equipped applications laboratories that can run samples. Prospective buyers are urged to take the time to run thesample before making a purchase. Most samples can be run isocratically; however, for an initial purchase, gradient elution is a strongly recommended capability. It is essential in research and method development and lessusefulin routine quality control. A Tied wavelength (254 nm) UV photometer is recommended as a standard component for everything exceptgel permeation chromatography work. Most sample types show someabsorbance at 254, and it is a robust, inexpensive, and sensitive detector. Sample typesthat might require a variable wavelength UV or refractive index detector include sugars, fatty acids, triglycerides, most polymers,and nonaromatichydrocarbons. However, in view of chromatographic separation of oligomers, the author’s first choice is a refractive index detectorthat can be used for both sensitivity or selectivity. Optionally, this detection system maybe combined withUV detector. Modular systems are more flexible and usually less expensive than integrated systems. They allow start-up with a modest investment and can be upgraded later. Modular systems usuallyrequire some experienceon the part of the chemist and may require more “playingin the lab”initially to set up and optimize the modules. Integrated systems use matchedcomponents
Liquid Chromatography
191
in a fully assembled unit; start-up time is minimal and the manufacturer often provides installation, start-up assistance, and some training. Integrated systems are usually more expensiveand easier to automate, butthey frequently cannot be taken apart forswapping parts or troubleshooting. The buyer must finally choosea specific instrument manufacturer. In many cases the previous considerations will have narrowed the field to two or three candidates. Table presents the major suppliers and models of HPLC equipment (in alphabetical order). The most important factors are the manufacturer’s reputation in HPLC and the after-sales service. A good picture can be seen by talking to several local LC customers who have purchased equipment in the last few years. Try to avoid “good” or “bad” opinions created years ago, often in a different product line or associated with a particular person. A minor factor (in most cases) should be the relative cost, provided there is not more than variation. The important criterion is the price/ value; frequently, highly pricedunits offer more value.
F. Applications of Analytical and Preparative Liquid Chromatography
The were a very exciting period in the area of applications. Few separation problems could not be solved with either HPLC alone or in combination with other techniques. HPLC is used not only to separate and purify products of synthetic and naturally occurring reactions, but also to obtain intermediates of reactions, purify starting materials, and obtainenough of a purified compound for futuretesting or for structuraldeterminations. HPLC has expanded to include ion chromatography, affinity, immunoaffinity, and chiral chromatography in addition to the more common modes of adsorption, ion-exchange, normal phase, reversed phase, and size exclusion chromatography. Supports, besides the commonlyusedsilica,include other oxides carbon polymeric resins hydroxyapatite beads and agarose Packings come ina wide range of particle and pore sizes. There are specialty packings for affinity and immunoaffinity separations oligomers and macromolecules, and especially for biologically active macromolecules Mixed-mode and mixed-bed packings have been investigated as have been coupled columns for compounds with multiple functional groups Columns come in various lengths and internal diameters to solve any problems at hand. In addition to the commonly used stainless steel columns, glass-lined stainless steel and glass columns are now available as are plastic cartridges. The problem now is
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Liquid Chromatography
197
deciding which of the plethora of columns is the right one to buy, given that column prices are high and many academic laboratories have limited funds forequipment Several forms of preparative liquid chromatography have been developed according to various requirements for sample size and difficulty of the separation. Analytical or preparative liquid chromatography involves slightly enlarged column volumes obtained by either lengthening the column or enlarging itsinternal diameter. Larger columns allow difficult separations, but the back pressureand separation time soon become prohibitive. Enlarging the column diameter is thus the most practical means to achieve increased capacity. High-performance laboratory preparative liquid chromatography is currently performed primarily on columns cm long withan i.d. of 710 mm. Such columns hold g of silica gel and can handle sample loads from to mg, depending on the difficulty of the separation. A larger column cm long with an i.d. of cm) that holds approximately g of packing material is often used in the research laboratory. The optimum flow rate of such a column is mL/min, that can easily be accommodated by mostanalytical liquid chromatographic instrumentation. This size column is the largest that can be packed with conventional packing methodsand thatwill show reasonable column stability when handled carefully. Even larger columnsare needed for production-scale preparative liquid chromatography, and two solutions to this problem have been developed. The first employs enlarged systems similar to those used in analytical liquid chromatography with stainless steel columns filled with silica gelbased packing materials and high-pressure solvent delivery systems. The second, used primarily in biotechnology, uses soft gels in glass or plastic columns undermoderate pressure. Analytical columns are usually packed by pumping a slurry of the packing material at pressures of up to400-1000 bar. Packing fluid is forced at very high velocity through the column bed as it forms. This forces the stationary phase particlesinto amore or less stable bed with a porosity that is still far from what is theoretically possible, making the stability of these columns uncertain. Under prolonged use, further settling of the stationary phase may occur, a void will appear at the top of the column, and the efficiency ofthe system will be reduced. It is difficult, however, to pack large i.d. columns in this manner. Stainless steel columns of cm i.d. can accommodate the necessary pressures only whenthe wall is prohibitively thick. Pumps that can generate that required pressures while delivering the necessary volume of solvent
198
Chapter
simply do not exist. Early preparative liquid chromatographic systems avoided this problem by using coarser stationary-phase particles; particles with an average size of25 pm can indeed be packed simply bypouring them evenly into the column. Adding solvent to the particles without wetting them can improve dry packingresults. Glass or plastic columnscan be used for such large-particle columns, that have good stability because of the mild pressure drop and general chromatographic requirements of coarser particles. The recent tendency in preparative liquid chromatography, however, is toward high-efficiency columns usingsmall particles with a diameter of 10-25 pm. Packing problems are avoided by using compressed bed techniques in which dry packing material or a slurry is placed in the column that is then compressed. Very little liquid is forced through thebed during packing. Although bed compression was developed as a packing technique for large-scale columns, recent experience has shownthat it is also important in maintaining columns in an efficient state during the chromatographic run. Friction heat is generated in the column as the solventis forced through thepacked bed. Thisappears to be a problem for the small-particle columns used in modern preparative liquid chromatography. Such friction heat is a function of the linear flow velocityand viscosity of the solvent as well as the particle size and pressure drop over the column. With the larger particles and low viscosity solvents usedin normal phase liquidchromatography, friction heat is negligible. With smaller particle columns and the viscous solvents used in reversed phase liquid chromatography however, friction heat becomesa serious problem. opening appears at the column wall because of the difference in thermal expansion, coefficients between the packed bed and column wall material. In a 20-cm i.d. column, packed efficiently withWpm reversed phase stationary phase, a visible opening of several tenths of a millimeter appears during the firstchromatographic run. All solvent pumpingthrough thecolumn then passes along the wall and not through the packed bed, resulting in the “thermal wall effect” [649,650]. This problem can be solved by continuous bed compression during the chromatographic run such that the volume of the space available to the packed bed is continuously corrected. Use of columns that have been removed from the compressed packed station can result in thermal wall effects for reversed phase small-particle separations. Bed compression can, in principle, be achieved axially, radially, or by a combination of the two. Axial compression can be exerted from the top of the column, the bottom of the column, or both together, and the piston can be actuated either mechanically or hydrolytically. Because mechanical
Liquid Chromatography
199
pistons require a lot of operating space, hydraulic pistons are preferable from an installation point ofview. Radial compression can be obtained by gas or liquid pressure on a flexible sheet againstthe column wall insidethe metal column. The flexible wall obviously must be inert to the solvents used and must withstand frequentbending.Combinedradial and axialcompression is obtainedby pressing a wedge-shaped shoft in the column. The term dynamic axial compression was recently introduced[649]; such a term is useful in differentiating more clearly between “dynamic preparative liquid chromatography” (continuous bed compression) and “static preparative liquid chromatography” (without bed compression). With the advent of commercially available large-scale compressed column instrumentation [649],this technique has become widely used the in pharmaceutical industry. For large-scale industrial preparative liquidchromatography, the economics of operation are important. The cost per kilogram of processed compound is between 50 and 500 US$, which is not prohibitive for compounds of high commercial value, dependingon the difficulty of the chromatographic separation. Solvent handling and recovery account for much of the operating costs ofthis type of large scale system; other costs include instrumentation,installation,maintenance, and labor. Stationary-phase costs depend greatlyon whether the silica gel must be derivatized. Although a large number of octadecylated silica gels are available commercially for large-scale preparative liquid chromatography, all are different and will produce different alpha values for a given separation. It is thus extremely important to compare such materials on an analytical liquid chromatographic systemto find the one that gives the most efficient separation. Practically all analytical chromatography today is performed with mixtures of solvents,but it is almost impossibleto recover large volumes of a ternary solvent without changing its composition in the distillate. This problem can be avoided by usinga single solvent,but a single solvent does not often provide the desiredselectivity. The stationaryphaseis thus adapted to a particular separation problem by changingthe degree of derivatization, changing the derivatization reagent, mixingdifferent stationary phases, derivatizing with mixed reagents, or sequentially using different derivatization reagents on the same phase. Such special stationary phases may be expensiveat first, but in the final economic picture they may prove to be worthwhile. Because stationary phase packing material is expensive, particularly in the amounts required for large preparative liquid chromatographic columns, it is economically advantageous to regenerate used columns. Used packing materials can be dirtied by samples, lose bonded chains, or exhibit
200
Chapter
increased back pressure aasresult of fine particles that are generated during packing or by continuous compression. Although some researchers believe that removal of fine particles by reclassification introduces unwanted changes in selectivity because new active surfaces are being generated, this does not appear to be the case. The increase insurface area from compression is extremely small,and even if all the particles were halved, the surface area of a 20-pm packing material would increase less than 1 m2/g, compared with a total specific surface area of 200 m2/g. Regeneration of used packing materials isthus a viable proposition. The feasibility of a production-scale liquid chromatographic process is, ofcourse, determined by running the separation on analytical instrumentation first. Itis, however, practically impossible to reproduce exact analytical liquid chromatographic data on a larger scale system. Even when the two columns are packed with the same stationary phase using the same packing material (which is normally not possible), wall effects will result in the columns having different packing densities, which in turn cause variations in retention data. Nevertheless, analytical results can be a great help in optimizing a preparative liquid chromatographic separation. In spite of the fact that the retention mechanism in reversed phase liquid chromatography (RPLC) still remains controversial, many applications liquid chromatographic separation of oligomers have been reported (see Table 19). RPLC yielded separations of lower oligomers far superior to those achieved bygel permeation chromatography (GPC). Styrene oligomers having polymerization degrees N, up to 11 were separated on octadecylsilica columnselutedwith pure acetonitrile [750].Better separations can be achieved usinggradient elution with an increasing concentration tetrahydrofuran (THF) in water [751-7541 or of THF in methanol [755]. The influence of various factors on the separation of styrene oligomers has been investigated, such as the nature, pore size and surface area of chemically bonded nonpolar phases and solvents used as the mobile phase [756,757]. Some combinations ofbondedphases and solvents used as the mobile phases allow both the separation of styrene oligomers, according to their degree of polymerizationand theresolution of some stereoisomers of polystyrene oligomers [756,757].Nonaqueous reversed phase liquidchromatography on octadecyl-silica columnseluted with a gradient of dichloromethane in methanol separated styrene oligomers having values Nof of up to 20 and some higher polymers of low polydispersity [758]. The separation is believed to occur by a combination of hydrophobic and precipitation mechanism and a theory describing this process was developed [759]. Aqueous and nonaqueous reversed phase liquid chromatography on phenyl-bonded
Liquid Chromatography
201
phases were used for isocratic separations of styrene oligomers with THFwater, acetonitrile-water or THF-n-hexane as mobile phases, and an equation was derived to describe the relationships between the logarithm of capacity factors, k', of the oligomers and both the degree of polymerization and the concentration of the organic solvent in water as the eluent [760,761]. Normal phase liquid chromatography (NPLC) on nitrile-bonded phases eluted witha gradient of dichloromethane in isooctane separated the first twelve styrene oligomers, and a linear relationship between log k' of the oligomers and thedegree of polymerization, N , was reported [762]. Similar results were achieved on silica gels with a convex gradient of dichloromethane in n-hexane, which allowedthe partial separation of 8-10 low molecular weight styrene oligomers [763]. Whenthe mobile phase was comprised of THF and n-hexane or of ethyl acetate and n-hexane, the styrene oligomers were separated only accordingto the number of oligomer units, whereas withdichloromethane-n-hexane,separation of the stereoisomers of the styrene oligomersalso occurs [764]. The retention behavior was explained on the basis of additive contributions to the adsorption from identical oligomer unitsand from end groups [765]. A calibration method using alkylbenzene calibration series and two indices to characterize the retention of each solute over a wide range of mobile phase compositions has been introduced [766]. One index, nE, accounts for thehydrophobicity of a solute and the other, qi, for thepolarity of its functional group(s) interacting with mobile phase components. This approach makes it possible to predict the selectivity changes induced by changes in the mobile phase compositions and may to used to predict relative and absolute retentions under isocratic or gradient elution conditions in binary and ternary mobile phases [767,768]. The lipophilic and polar indicesmaybecalculated from the additive contributions of structural elements [767]. with homologous series [769],a regular increase inthe logarithms of the capacity factors with an increasing number ofrepeat structural units was observed for some oligomeric series studied systematically in reversed phase systems, such as for oligoethylene glycol phenyl ethers, in agreement with the Martin rule [769].
G. Unsolved Problems and Future Trends of Liquid Chromatography In liquid chromatography (LC) there is a lack of a reliable modelto predict the capacity factor fora wide range of solutes, the retention mechanism on some phases isnot fully understood, and data on diffusion coefficients are scarce.However, approximations havebeenroutinelyappliedover the
b
8
Ghro ~ aogr t a p h for ~
ligo~er
n
2~000 2,0~-6,000
Stationary Phase
luent
Silica gel Silica gel ben~~ne-eth~nol
3,100 Silica gel ~ Q 0 - 4 Silica ~ ~ gel ~ , ~ ~ligobuta~i~ne 80Q-1,900 Uligobutadiene 2 ~ 5 ~ligoisobutylene 2,200 ~ l i g o i s o ~ylene ut 900 ~ligoisop~ene 3,100 Gopoly(1,3-butadieneisoprene) Copoly(1,3-b~tadieneisoprene) Chpoly( 1 ~ ~ - ~ u t ~ ~ i e n e - I ,~Q0-3 iso~rene~ 294 Gopoly(d ,3-~utadien~isoprene) Co~oly( 1,3-~utadieneisoprene) Copoly( 1~ ~ - ~ ~ t ~ ~ i e n e isQprene)
Silica 0 gel Silica gel Silica ~ gel Silica gel Silica gel Silica gel
CCt,, toluene, CKCl,, dichloroethane CGl~-~~Gl~-e~hanol
~bservations
ef.
G~adientelution Gradient elutiQn Gradient elution Gradient elution Gradient elution lsocratic elution
[651,652] [652-6541
~ r a d i e nelution t Gradient elution Gradient elution Gradient elution ~ r a d i e nelution ~ ~ r a d i e nelution t
[6601 [661] [662] 16581 f658,663f 16621
I6551 1656,6571 [658] [659]
lsocratic elu~ion
f
Silica gel
~ r a d i e nelution t
j16651
Silica gel
~ r a d i e n~lution t
16663
Isocratic elution
I6671
Gradient ~ l ~ t i o n 16583
C o ~ o l1y, ~ - ~ u t a d ~ e n e isoprene) Copoly~ 1,3-butadie~ep~perylene)
Silica gel
eel4-
Gradient elution
[6~~1
Gradient elution
[6693
G ~ ~ ~ ieel n~t t ~ ~ [ 6n 7 ~f ~ ~ 7 ~ Copoly~tetra~ydro~uran~~Q~ylen~glycol~ Oligotetrahydrofuran Copoly~tetrahydr~fu~anepichlorohydrin) ~ ~ ~ o l y ~ e toxidehy~en~ 500-5,000 Silica gel ~ r o ~ y l e glycol) ne Oligo~r ~pyleneglycol 5 , ~ OSilica gel ~ligoox~ropyl~~e ,OOO Silica gel ~ligotetr a~ethyl~ne500-3,000 Silica gel glycol ~ligodi~thyl~neglycol ~ 0 0 - 2 , Silica ~ gel adipate ~ l ~ g Q ~ b dycol) ut~le~ 1~ ~ O - ~Silica , Ogel~ Tiokol 2 , ~ 0 0 - 3 , 0 Silica ~ gel ~ligosulfide Glass Epoxy resins Silica gel ~ ~ h a - ~ y d r o ~ ~ - o ~ e g ~ -2,000 Silicagel ~enzoligo~ 1,3,6-trioxane) ~ycloole€in oli~o~ers ligoacrylate ~ligoca~r~l~ctone h,
t2
ethyl e t ~ketone ~ l (
Isocratic elution
[6721
I ~ u ~ r a telution ic Isocratic elution
[673] 16741
EK -et~anol(6:2:1)
MEK
en~ene-ethanol(75/25) CC14-6 ~en~e~e-hexane ~etra~~~r~~uran THF
~socratic~ l u t ~ o n[ ~ ~ 5 , 6 7 7 , 6 ~ $ f ~socraticelution [67~-6$6] Isocratic elution [6 $ 7 - ~ ~ 0 1 Isocratic elution
[691-6961
Isocratic elution Gra~ientelution Gradient elution Isocratic elution Isocratic elution
~6~7~6~$1 ~69~,700] [701,702] ~703-~07~ 170~~70~1
socrati~el~tion [7 G r a ~ i e nelution ~ [710-7 121 ~ ~ aelution ~ i ~[713'f ~ t
Table 19 Continued -
Oligomer
!
M"
Polycarbonate
9,000
Maleic anhydride oligomers
3,000
Oligoesters Oligoacetilene Oligostyrene Oligo(phenylene sulfone) Epichlorohydrine oligomers Oligo(4-vinylpyridine) P henol-formaldehyde oligomers Oligo(viny1naphthalene) Polynuclear aromatic hydrocarbons Oligo(styrene-acrylate) Peptides Oligo( 1,3,6-trioxane) Oligonucleotides Oligosaccharides
1,500 1,000 3,000 1,000 5,000 1 300
Stationary Phase Organic packings Organic packings Silica gel Silica gel Silica gel Silica gel Silica gel Bondapak
1,500 2,000
LiChrosorb
4,500 1,500 1,800 2,000 4,000
LiChrosorb Lichrosorb
Eluent
Observations
Ref.
Gradient elution Gradient elution Hexane-MEK( 8:92) -
Tetrahydrofuran CHCl,-CCl, CHC1,-CC1, Pentane-CH,OH Methanol( 80% )-water(20Vo )
Tet r ah ydro furan
Isocratic elution Isocratic elution Isocratic elution Gradient elution Gradient elution Gradient elution Isocratic elution
17181 [ 7 19-7241 17251 17261 [ 727,7281 16861
Gradient elution Gradient elution
[730-7341
Gradient elution Gradient elution Isocratic elution Gradient elution Gradient elution
[735-7431 [ 744,7451 17461 17471 [ 748,749J
[ 716,7 171
t7291
Liquid Chromatography
205
years and some questions still remain which are not very clear to users. The questions are more numerous in liquid chromatography than in gas chromatography. These questions may be classified in two categories: those regarding the solvent effects and those which are involved in retention problems. In normal phase liquid chromatography (NPLC) the SnyderSoczewinski displacement model states that retention is given by eq. 110 [7701 : logk' = log(
%) + a(S" - €'AS) +
&as
Vm
where a! is the adsorbent activity, V, and V, are the volumes of stationary and mobile phase, respectively, E' is solvent strength parameter, and A, s are constants. There is no adsorbent of standard activity to refer to and a! is determined from chromatographic measurements. In the model (eq. 110) the solute retention in a binary mixture of solvents (apolar diluent polar modifier) is given by
+
l o g k ' = a - blog(X,) where X, is the mole fraction of the polar modifier. When using mixtures of the same eluting strength the same retention should be observed. This is not the case as indicated by data in Matyska and Soczewinski [771]. The different retention data obtained in the experiments with heptane and chloroform are normal since solvents exhibit their own different characteristics. Differences in selectivity are the result of displacement and solvation equilibria in the mobile phase [ 7721. Identical retention is observed with solutes of identical properties. T o our knowledge there is no predictive theory of selectivity to account for these differences. This problem is more acute in reverse phase mode liquid chromatography (RPLC) and very troublesome when dealing with optimization procedures. Observed retention at the three selected solvent compositions of the triangle apices is often a matter of perplexity [773]. This can be overcome but the problem is complex when 3 or 4 solvents are involved. Peak crossover occurs when the whole surface of the mixture design is considered and one cannot predict the relative solute behavior. Solvent effects are weak and cannot be measured accurately; they are the consequence of individual effects which can be synergistically reinforced or diminished. In RPLC the retention mechanism is still not fully understood. Retention modeling is required for any computer-assisted optimization procedure and description of the retention behavior of the solutes under isocratic conditions is a key factor to gradient elution. The prediction of retention time and optimization of separation conditions from physicochemical properties is not com-
Chapter
206
pletely successful, the correlation between AHand k’ is only fair. One very serious drawback is the stability of the packing; only few manufacturers can provide guaranteed reproducible packings. Moreover, it is common practice to use columns withvery different mobile phases and this is detrimental to the reproducibility of retention. The simplest relationship is kw Ink’ = In
- SI$
(1 12)
where I$ is the volume percent of organic modifier in a binary mixture: waterlorganic modifier. Thislinear relationship onlyholds true over a limited range of composition (Fig. The linear part is smallest whenthe solute is capable of hydrogen bonding. To account for deviations from linearity, second order or more sophisticated relationships have been derived. The problem is that the range of linearity is not known. To enhance the domain Johnson [774] used the solvatochromic theory of Kamlet and Taft and compared the linearity In k’ = f ( 4 ) and In k’ = f(so1va-
log k’
/
thylbcnzene
1.5
Nllrobcnzcnc
1.c
c
.
00
GO
.
.
40
,
. 20
.
0
Figure 26 Typical relationships between log k’ and volume fraction of CH,OH in water/methanol. Solid lines linear regions. (Adapted from Ref.776.)
Liquid Chromatography
207
tion parameter). They observedbetter linearity in the lattercase but did not go beyond 80% in acetonitrile. In eq. 112, kw is the extrapolated value of k’ when 6 = 0 (pure water). Starting with the two binary mixtures (watedacetonitrile and water/ methanol) the same valuefor kw should be observed. Thisis very often not true. The value of kw must be considered asthe intercept of the line witha given mixture. We have no prediction model for binary mixtures and, moreover, none for ternary or quaternary ones. Jandera [776] published a paper on ternary solvent optimization. The lack of reliable theory prevents the routine use of computerizedoptimization. An index system does not exist in LC. Smith and Burr [777] proposed alkylaryl ketones asstandard solutes. The retention index of a solute is the sum of the retention of a parent compound, of the increment for substitution groups, and interaction terms. With benzene derivatives the parent compound is obviously the benzene. Unfortunately the indices are not very reliable for different solvent compositions and their use in optimization theory looks difficult. The main problemis the accurate determination of k’ .Each molecule may have its own volume [778] and a review on this topic has been published by Malik and Jinno[779]. The questions involved in retentions problems are numerous. With polar bonded-phases the exact nature of the retention on a organophase is still a matter of dispute since some papers claim that residual silanols are only involved in retention [780]. No definitive explanation is given for the fact that cyano phases exhibit basic properties in chloroform and acidic properties in methyl t-butylethers [781]. Based on past experience and current needs, it is possible to predict trends in separation techniques. Unfortunately, I donot have a crystal ball to see preciselythe developments that will take place in the future.The only thing one can be sure of by daring to write sucha paragraph is that a good deal of what is said will come back to haunt the author. “Those who ignore the past are bound to repeat it,” but I propose to approach the topic of this chapter by first offering a view of how liquid chromatography development originates in the past and finally, I would like to answer the questions of what needs to be the view for both instrument development for the near future, and what techniques must be first researched and what discoveries one could hope for which would generate another direction for development in separation. It would be useful to have an independent measure of what stage of development a given separation method has reached. Such a ruler would help in predictions of the future in, or of, a given method. No certain
208
Chapter 3
method has been established as yet, but there are a number of approaches including market surveys and total sales. The most obvious need for HPLC instruments will be in biotechnology and the life sciences. As the biological sciences continue to migrate toward a molecular basis, chromatography will play an importantrole and the market will expand. Separation science needsto direct its efforts toward other futures and othermethodologies and there are ample challengesto do New challenges in environmental monitoring and forensic medicine will requires sophisticated and reliable separation techniques. HPLC will play an important role in molecular biology not only on the analytical scale, but also on thepreparative scale. Both fast andmicrobore column HPLC will be used for various phases of the work, especially in mapping the human genome. HPLC will also be a vital tool in cancer and AIDS research and diagnosis and in determining biochemicalmarkers for detecting and monitoring the course of many inherited genetic defects and otherdiseases. In biotechnology,high-speed separations willbeused for process monitoring of fermentation and growth media. Microbore columns with sensitivities in the molerange will be used routinely, and singlemolecule manipulation may be possible because extreme sensitivity -”) is within sight using either capillary HPLC orcapillary electrophoresis. Another potential use is the separation of cells and the rapid identification of viruses and bacteria. HPLC will also continue to be the mainstay of the pharmaceutical industry, not only in analytical laboratories, butalso for quality control of starting materials and final products; for on-line process monitoring, and, on the preparative and processscale, for the isolation and purification of drug products. The increased sensitivity of capillary HPLC and thevery rapid analysis that can be achieved withshort columns will make this technique indispensable in biochemistry, molecular biology, and themedical sciences. The great potential of HPLC-coupled techniques will be valuable in toxicology, pharmacology, and forensic medicine. Because greater emphasiswillbeplaced on the stringent requirements of regulatory agencies, HPLC/MS will become a necessity in many laboratories and will be used routinely in organic synthesis and medicinal chemistry to separate, purify, and determine molecular structures simultaneously in one sample. Emerging applications in the life sciences will includethe analysis of carbohydrates (especially glycoproteins), phospholipids, and surfactants. With miniaturization, instruments can be taken into the field for environmental and clinical work, and possibly even into outer space. HPLC will also be important in monitoring the purity of materials used by the electronics industry in manufacturing processes, especiallyfor computer chips.
Liquid Chromatography
209
Most ofthe advances in separation in oligomericand macromolecular systems has arisen outside of the traditional chromatography community. There are numerous reasonsfor this. Part of the difficulty lies inthe preference by separation scientists for small molecules and the easy relationships of directed forces, sample kinetic theories, and other qualities common to such systems. Future advances in large molecule (including oligomers), if they are tocome from thechromatography community, will needto include the abandonment of this comfortable area and the application of a good deal of chemical insight as it relates to oligomers and polymers, which occupy space, have many functional groups, differ in chemical structure and in molecular size; consequently, results of separation can change with changing separation conditions. “More than 90% of liquid chromatography is reversed phase” is a remark one currently hears quite often in some circles. This is true if one ignores all exclusion chromatography done by those who must deal with synthetic oligomers and polymers including biopolymers. A large number ofvery practical separation problems are amenable to solution by RPHPLC, and that is certainly why it remains popular. This should not be construed that NP-HPLCmethods have been eliminated because they have no value. Certainly some of the separations currently carried out on reversed-phase with additivesto improve resolution might be better done by normal phase. There are, however, many more gaps in the scientific basis for designing normal phase systems than are left in predicting reversedphase behavior. The problems with normal phase are the volatility and flammability of the solvents, their relative cost, and the lack of much research to determine the requirements for producing optimal, bonded, normal-phase packing materials. Unless commercial interest in pursuing normal phasecan be stimulated bya potentially large market need, itis unlikely that much will bedone in improving the stateof normal-phase methods. Liquid chromatography is still in a growth phase because of its adoption by scientificareas that can not ordinarily use gas chromatography as a routine tool. Included in these are those devoted to characterization of polymers and especially the knowledge of biologically active oligomersand polymers, ions and very water soluble compounds. The demand for very sophisticated, multisolvent, multiwavelengthinstrumentation is not seen as yet in much ofthis community. Manyof the “bio-problems” are solved with binary gradients and single-wavelength detectors. This will undoubtedly change as the potential of the technique is recognized and the need for selectivity control increases. There are many problems to be investigated and solved in this arena. The trend in the future willbe toward “bigger and bigger” and “smaller and smaller” instrumentation. To allow easy use of capillary col-
210
Chapter 3
umns, instrumentation properlyengineered for thesecolumnsmustbe made commercially available. Users will need microcolumn-LC to interface more easily with mass spectrometers, with other detectors such as FT-IR, or with other techniques such as capillary electrophoresisor gas chromatography. Miniaturization of instrumentswill also mean using less solvent and column packingand will conservelaboratory space. In this decade there will be great activity in the development and monitoring of specialized column packings. Although work in this area started in the the efforts will intensify. Better and more effective chiral packings will be needed to satisfy the pharmaceutical industry’s stringent requirements for enantiomeric purity of drugs. Affinity and immunoaffinity columns will be of the utmost importance for the production of highly purified biotechnology products because regulatory agencies both in United States and in Europe will demand ultrapurification to remove all debris from thehost cells. Columns that have a hydrophilic exterior and a hydrophobic interior willbe in demand for protein and peptideanalysis, as well as for the characterization of functionalized oligomers. These packings must be of small particle size and large pore size. Although they are currently available, more sophisticated versions of packings will be developed with solid support other than silica. Packingsthat arespecifically designedfor nucleic acids, oligonucleotides, nucleotides, nucleosides,and their bases, as well as adducts of these compounds, are need for biotechnology and for studying disease processes and environment. Chelate packings that are selective for various metal ions will be of interest for monitoring metal contamination in water. Another interesting type of packing is the cyclodextrins. Small molecular weight compounds are excluded because of their limited steric access; thus, these packings can be used as cleanup columns priorto analysis or for purification of small moieties. Eventually, for every compound there will bea packing. Silica wasthe solid support of the but other supports began appear in the latter part of the decade. Organic resins are making a comeback after declining in popularity in the and early These supportshaveadvantages,as do polymer-coatedsilicas,especiallyinbiotechnology. Porous graphitic carbons also have great potential as solid supports. They are chemically unreactive, can be used in a wide pH range, are highly reproducible and stereoselective, can be modified by adsorption of high molecular weight materials,and can be usedfor size exclusion.The major limitation of this support currently is the dearth of literature on publications and separation conditions for various compounds. Mixed-mode and mixed-bedcolumnswillbecommonlyused. The mixed-mode technique will be used for column switching or for various
Liquid Chromatography
21 I
types of columns in series(e.g.,cyclodextrin or exclusion, followed by reversed phase and/or ion exchange), or a packing material on which two or more functional groups are bonded. Mixed-bed columns contain two or more types of packing materialsfor example, anion and/or cation exchangers mixed with a reversed-phase packing. The mode of operation can be changed simply by switching the mobile-phase conditions.In fact,it may not even be necessaryto have mixed beds. Some ion exchangers can be operated in the hydrophobic interaction mode by changing the salt concentration of the mobile phase. The use of lasers as detectors will become increasinglyimportant. As a universal detector, the LSD will replace the RI detector for separations that require increased sensitivityor gradient elution. This detector can also be used to determine molecular weight. As a highly selective and sensitive mode of detection, LIF will play an important role, not only with HPLC but also with capillary electrophoresis. As capillary HPLC instruments become commercially available, it will be possible to adapt the best in GC detectors for usewith HPLC, such as the FID or the electron capture detector. However, as mass spectrometers decrease in size and price, and the interfaces improve, mass spectrometers will become the detectors of choice for obtaining structure information or for positive identification of an analyte, as in court cases or drug testing in athletes. The good old workhorse of the field, the UV-vis detector, will continue to hold its place ofhonor for routine analyses of compounds containing a UV chromophore. Its ruggedness, reliability, ease of operation, and reproducibility make this detector desirablefor laboratories where the ultimate in sensitivity is not necessary. In our laboratory, the UV-vis detectors purchased in the early 1970s have been used bya large number ofgraduate students and are still giving good results. Multiple detectorswill also play a major role in HPLC. Two or more detectors will beusedeitherinseries or via stream splitting. It can be helpful to have a universal detector determinethe number of solutes present in the effluent and one or more very selective detectors identify the compounds. The primary constraint is that the solvent system must be compatible with all detection systems. Computer optimization is here to stay even though some people are still reluctantto use these programs. As the younger chemists become more computer literate, resistance will diminish and a tremendous amount of time will be saved by computer optimization. The use of robots will also increase exponentially inthe next decade. Robots will be used for all routine tasks and will be especially necessaryin sample preparation and handling of potentially dangerous samples, suchas physiological fluidsfrom AIDS patients,other viral and bacterial materials,
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Chapter
contaminated environmental samples,and radioisotopes. Robotics will improve laboratory safety and will help to fill the gap due to the diminishing pool of science graduates available for jobs in industry and academia. In addition, the use of robots can increasethe number of samples reliably and efficiently processed per day, which is clearly an advantage in high-volume analytical laboratories. Control programs that use artificial intelligence will be the next stepin robotics. In the future, multitasking instruments will be commonplace. For example, after preliminary sample preparation by specialization robots, several instruments will be interfaced that all the steps from rigorous sample preparation to separation, peak identification, structure determination, and quantitation will be done automatically. Not only willthe instrument have several columnsand/or detectors, but it will be interfaced with capillary electrophoresis, GC, or mass spectroscopy. This combination of instruments and techniques is often referred to as multidimensional chromatography. In protein analysis, peptide mapping may be included in the multitasking program as will the determination of the base sequence in nucleic acidsin genome investigation. HPLC, alone or in combination with one or more techniques, will continue to be the separation technique that is the backbone of the analytical laboratory, especially in the pharmaceutical and biotechnology industries, because of the ease of sample preparation, automation, speed, and sensitivity. In the future, fast HPLC may be used instead of flow injection analysis to monitor real-time fermentation processes that are used in biotechnology. Althoughthe dominant applications will bein the life sciences, HPLC will face new challenges in environmental testing and in forensic medicine. Better separation techniques are also needed in the chemical industries for the manufacture of adhesives, sealants, catalysts for petroleum processing, and materials used in the manufacture of microcircuits. Good preparative and process HPLC techniques are required to separate, isolate, and purify most consumer products such as food, drugs, vitamins, and cosmetics. Several separation techniques will be competitive with HPLC in the next decade: capillary electrophoresis, supercritical fluid chromatography, countercurrent chromatography (CCC), and field-flow fractionation (FFF). However, Ido not believe that these techniqueswill replace HPLC. Because of its ruggedness, versatility, and separating power-especially for watersoluble, nonvolatile, thermally labile compounds -HPLC will maintain its solid position. Although capillary electrophoresis isa strong competitor in the separation of large biopolymers and biologically active molecules, more research is needed in injection systems, detectors, and peak identification before it can achieve its full potential. HPLC willbeused for routine
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analysis of molecules with molecular weightsin the range of 200 to several thousand. GC will continue to be the method of choicefor thermally stable, volatile molecules that have a molecular weight below 200, whereas capillary electrophoresis will be the method of choice for biopolymers. Supercritical fluid chromatography will be the preferred preparative technique if moremobilephases are found inwhich analytes are soluble. major advantage of this technique is the case of removing the solvent from the product solution. CCC is also useful for preparative work and has been used recently in the purification of peptides and proteins. However, many researchers prefer HPLC because they are able to scale up their analytical separations easily. Instrumentation for FFF currently is available, and in the next decade will be used in laboratories for theseparation of macromolecular or particulate species. Although other separation techniques are available, HPLC will not be replaced as the mainstay of the analytical laboratory, where all types of medium-sized molecules must be separated. Instead, in the 1990s GC and HPLC will be joined in the laboratoryby capillary electrophoresisand, for specific needsor problems, bySFC, CCC, and FFF. growing recognition ofthe potential formation of artifacts on column can be found in the current literature. This has many implications for the continued spread of LC into areas such as molecular biology. Artifact formation in gas chromatography has always been a problem and can be expected when labile substances are examined. The occurrence of artifacts is less a problem in small-molecule liquid chromatography and has been ignored in some earlystudies of the application of HPLC to diagnosis, for example. Much research will be needed to identify the likely occurrenceand cause of artifact formationin the separation of labile biomolecules if both methods of determination and collection of pure materials is to be reliable achieved. The future of chromatography seems quite bright, as does the future of molecular science. The future in chromatography is less clear. It will be fascinating to watch what happensin the next few decades.
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4 Gel Permeation Chromatography
INTRODUCTION In the landscape of liquid chromatographic methods,gel permeation chromatography (GPC)occupies a special place. The arguments are numerous which cansupport the differences betweenGPC and many other procedures that form liquid chromatographic method. In GPC, macromolecules are separated according to their hydrodynamic volume. This separation results from a decrease in the entropy of macromolecules when they pass from the channels of the mobile phase of the chromatographic columninto the pores of a stationary phase. In the adsorption form of liquid chromatography (LC),additional retention is observed. The elution of macromolecules in this instance is determined not only by entropy changes but also by the enthalpy changes that they undergo inthe interphase transition. The reason for the enthalpy changes is the energetic interaction between the macromolecules and the stationary phase matrix. The magnitude of this interaction is proportional 258
omatography Gel Permeation
259
to the number of adsorbing units of the chain. For an adsorbing homopolymer it is a degree of polymerization. In the case of heterogeneous polymers, it is possible that only one kind of unit interacts with the packing. Therefore, the magnitude of this interaction is proportional to the number of such units in the macromolecule. Consequently, the chromatograms obtained by GPC show distributions of the macromolecules of the sample according to size, whereas in LC the chromatograms reflect both this size distribution and also the number of the adsorbing monomer residuesin the macromolecule. Since the general liquidchromatographic instrumentation and column techniques are becoming an integral part of GPC, it is useful that practitioners be acquainted with the equivalences and differences in GPC and general LC technology. There are four ways of reporting conventional LC peak retention: retention time (t,), retention volume ( V,), peak capacity (k‘ ) and solute distribution coefficient (KLc). The simple experimental value,t R , measured by the time required for a peak to elute from the column following injection, is useful only for comparing peaks that have appeared in the same chromatogram. The value of tRis sensitiveto changes in experimental conditions such as flow rate and the specific columns used; therefore, it is not very specific for defining sample components. The retention volume V, is a more fundamental quantity in that it accounts for flow rates differences. To calculate V,, the mobile-phase flowrate, F,must be known aswell as the t R values, since V, = Ft,. While peak retention reported as V, is not subject to flow change, it can still vary with differences in column size and instrumental dead volume. Such variations are inherently compensated for with the more basic retention parameter, k ’ . Physically, k’ represents the ratio of the weight of solute in the stationaryphase to that in the mobile phase. Thus the weight fraction of solute remaining in the mobile phase is 1/(1 k ’ ) . For an unretained peak, tR = to,k’ = 0, and the value for the solute weight fraction in the mobile phase equals unity, meaning that the solute resides only in the mobile phase. Since solute migrates only when in the mobile phase, the retention time should be inversely proportional to this weight fraction:
+
or
and
Chapter 4
260
assuming constant flow rate, where V , = Ft,, for the retention volume of the unretained solute. Although widely used for comparing conventional LC data, values of k' still do notcompensate for differences in the stationary-phase concentration caused by the difference in the surface area and porosity of the column packing. Peak retention, or value of k ' , increases with increasingstationary-phase loading. account for differences instationary-phase loading, the parameter KLc should be used to define retention. In fact KLcis the only parameter that can uniquely define the retention characteristics of different organic compounds in conventional LC experiments witha specified column packing, mobile phase, and temperature. Physically KLcis the ratio of solute concentration in the stationary phase to that in the mobile phase. For a given mobile phase and column packing, values ofK,, uniquely reflectthe basic thermodynamic balance of solute between the phases. Assuming that the equivalent liquid volume for a stationaryphase is V,, K L C is related to k' by
Inserting this relation into eq.
one can show that
Eq. 5 represents the equilibrium theory of conventional LC peak retention. It explains why the experimental value of V, is determined solely by the thermodynamic balance ofsolute distribution between phases. In GPC, solutes are partially excluded from the column packing and elute ahead of the solvent peak. As a solute band moves along with the solvent downthe column and around thepacking particles, the solute molecules repeatedlypermeate or diffuse in and out of the pores of the packing. The driving force for the process is the concentration gradient between the pores. While in gel filtration separation (GFS) of naturally occurring macromolecules, or in GPC separation of small molecules, several distinct peaks may be obtained; in synthetic polymer analysesthe GPC chromatogram or elution curve usuallyis just a broad, continuous elution pattern. To extract polymer molecular weight distribution (MWD) information from a GPC chromatogram, the exact MWD versus V, calibration relationship the GPC column is required. In discussing LC retention, the volumes of the mobile phase inside
Gel
261
and outside of column packing are grouped into one volume term, V,, the retention volume ofthe solvent peak(eq. 5). Since all peaksin the otherLC methods elute after V,, it is not important to distinguish between the stagnant versus the moving parts of the mobile phase volume,V,. Subdivision of V, is necessary for explaining GPC (where the term mobile phase simply means, in GPC,the carrier solvent), because the stagnant part of the “mobile” phase residing in the pores is, in effect, the “stationary” phase for GPC separation (Fig. 1). To avoid confusion with the stationary-phase volume V, in the other LC methods, the stagnant structure in GPC is designated as the internalpore volume. The remaining liquid volume in a GPC system is designated as the void volume V,, which is mainly the interstitial liquid volume between the packing particle.By definition, then V, = V,
+ V;.
(6)
Size separation in GPC is the result of differential solute distribution between the solvent spaces outside and inside the pores of the column packing. Thissolute distribution can be described bythe GPC distribution coefficient KG=, that represents the ratio of the average solute concentration in the pores to thatoutside the pores. Because ofthe size-exclusion effect, not all the pore volume & is accessible to large solute. Solute concentration inside the pore decreases with increasing solute size. In effect, then, the total accessible liquid volume for different-size solute is not (V, but (V, KcPC&).Substitution of this accessible liquid volumefor V, in eq. 6 can be minimized by using inert column packings to avoid interference of surface effects on GPC solute retention. With negligible surface effects, GPC retention can be approximated as
+
+
Figure 1 GPC retention mechanism: I, mobile phase; 11, stagnant mobile phase; 111, porous packing.
262
Chapter 4
V, = V0
+ KcpCK
(7)
The values of KcPCcompensate for column size variation. For any GPC column regardless of size, KGpc= 0 at exclusion and KGw = 1 at total permeation. Intrinsically, GPC is a low-resolutiontechnique.Unlike other LC methods, which can be developed to resolve up to hundreds of component peaks representing many column volumes and extended retention times, GPC separations are constrained to occur within the limits of the packing pore volume. Thus only few peaks can be fully resolved in GPC. The large difference in peak capacity between GPC and other forms of LC can also be explained in terms of basic retention parameters. The value of KGpcis constrained to be between0 and 1, which means that solute distribution favors the unrestricted space outside the pore. On the other hand, values of K,, are unlimited, which means that solute distribution favors the stationaryphase, as in the case for most LC peaks. This difference in peak capacity between GPC and other LC methods is indicative that different thermodynamic balances are involved in controlling solute distribution. As will be described in the following, GPC is uniquely different from the other LC methods in that it is a chromatographic process controlled by entropy, notenthalpy. Direct use of terminology traditional to LC in GPC applications can sometimes be awkward. In GPC (Fig. 1) the size separation occurs only within the mobile phase volume, V,, where different size solutes distribute differently between V, and K, that is, between the solvent moving outside the packing and the stagnant solvent inside the pores of the packing. The distribution favors V, more for larger solutes. According to LC terminology and eq. the GPC chromatogram would have to be interpreted with awkward negative values of k ’ , since V, V, in GPC as solute elutes before the solvent peak (i.e., tR < to and k’ 0). This is why the distribution coefficient KcPCis used in GPC as the peak retention index instead of k’ as in conventional LC. For the same reason, the separation factor a, defined in conventional LC the ratio of k’ for two solutes, is not used in GPC. According to eq. failure todistinguish the moving and the stagnant parts of the mobile phase doesnot affect the estimation of k ‘ . However, it does causean errorin the calculation of solvent velocity,v:
where L is the column length. It is a known fact that polymers are not unique substances but tures formed from molecular species that can distinguish themselves through
Gel
263
molecular weight and composition or chemical structure. The direct consequence of this situationis that in the polymer’s casethe molecular weight is expressed by average values generated by the existence of a distribution of the molecular weight and physical constants are replaced by transition states. GPC was born outof the need to have an efficient deviceto determine molecularweight distribution in naturaland synthetic polymers. This method succeededin transforming polymer fractionation from an academic activity into a routine work also accessible for unsophisticated labs. GPC has eliminated on thespot the main disadvantages of polymer fractionation by classical methods: the huge time consumption, uncertain and unreproducible results, as well as tiresome work. However, 20 years have been necessary for thegel permeation effect to turn intoworking a methoduseful for oligomer and polymer fractionation. Since the 1925-1935 period when the gel permeation effect was discovered [ 1,2], in whicha pioneer’s role was held by the Romanian scientist Cernescu until the 1 9 5 0 ~ no~application was found to this effect. The first real application of gel permeation effect was made by Porath [4] who used this effect for separation and characterization of mixtures in biological chemistry.The method thus created, to be only applied inan aqueous medium, has been calledgelfiltration. However,in my opinion, the true historyof GPC begins in 1964 when Moore published hispaper “Gel permeation chromatography. A new method for the determination of molecular weightdistribution in high polymers” ( J . Polym. Sci., Part A, 2, 835, 1964). Immediately after that GPC has continually widened its application range. Identification of auxiliaries from polymers and quantification of oligomer presence represent only two of the main developments ofGPC in the analytical chemistry of polymers. Oligomer presence in polymers represents a natural state.Often oligomer separation determines their restoration in the polymer mass via degradative processes. Oligomers are to be called macromolecules whose molecular weight varies between 10’ and lo4 daltons. Beginning with the dimers and ending with species with a molecular weight of several thousands, the oligomers represent a special, well-defined world, which has become extremely useful and particularly powerful. Many times the oligomers are considered to be the diplomats of the polymer country [5,6]. During the past ten years, there has been less emphasison GPCtheory and band-broadening studies and more focus on applications. However, to finish off the theoretical basis of GPC, three essential elementsare needed: to know the separation process, to create a convenient and realistic model for the solute particle, and, finally, to achieve a correct image of the packing.
264
Chapter 4
II. THEORETICAL BASIS Gel permeation chromatography is sometimes viewed as a liquid chromatographic separation technique, sometimes as a molecular weight and molecular weight distribution method specificfor high polymers and oligomers. It fulfills the latter role only when the column is calibrated with appropriate standards; itis not always clear whatconstitutes an appropriatecalibration. Unlike other modes of chromatography, GPC is an entropically controlled separation technique that depends on the relative size or hydrodynamic volume of a macromolecule with respectto the size and shape of the pores of the packing. In GPC solute-packinginteractions are absent. In GPC as solute molecules migrate through the chromatographic column, they transfer back and forth between the moving and stationary phases, constantly redistributing themselves between the phases to satisfy the thermodynamic equilibrium. Under normal chromatographic conditions, solute distribution approximating thermodynamic equilibrium is achieved. Thermodynamic equilibrium is defined as the condition in which the chemical potential of each solute component is the same in the two phases. For dilute solutions at equilibrium, solute distribution can be related to the standard free energy difference (AGO) between the phases at constant temperature and pressure: AGO = -RTln K
(9)
with AGO
=
- TASO
(10)
where K is the solute distribution coefficient, R the gas constant, T the absolute temperature, and Moand ASo standard enthalpy and entropy differences betweenthe phases, respectively. The theory of macromolecular GPC was essentially formulated by Cassassa and coworkers 17-91. Their theory is based on the calculation of changes in the entropy of a macromolecule as it penetrates from themobile phase into a sorbent pore, and make use of a model of a flexible-chain macromolecule in a thermodynamically idealsolvent, assuming a low polymer concentration in the solution and the quasi-equilibrium nature of the chromatographic process. The chief result of the theoretical studies performed by Casassa[7-9] was a universal relationship between the distribution coefficient, K, and the ratio of the radiusof gyration of the macromolecule, r, to pore radius, R. For a model of slitlike pore of width 2R, this relationship has the following form [7]:
Gel
265
where the summation is performed for added values of m. In the limiting wide-pore and narrow-pore cases, the K vs. r / R relationship takes simpler forms:
It follows from eq. 13 that with large macromoleculesand narrow pores, at r > R, the distribution coefficient isnot equal to zero. This signifiesthat a number of large macromolecules penetrate into narrow pores, assuming elongated conformations that are different from theequilibrium conformations of macromolecules in solution. Penetration of large molecules into narrow pores is a specific feature of polymer chromatography, which Casassa [7] was first to recognize and that was not accounted for in other GPC theories [ 10,l l]. The validity of explaining GPC retention only in terms of thermodynamic considerations requires that the solute distribution in a GPC experiment be close to thermodynamic equilibrium. Thus GPC separation is controlled by the differential extent of permeation rather than by the differential rate of permeation. The results of the temperature, flow rate, and static mixing experiments clearly show that GPC retention is an equilibrium-controlled, size exclusionprocess [12-141. Thismechanisticmodelindicates that solute diffusion in and out the pores is fast enough with respect to flow rate to maintain equilibrium solute distribution. Thermodynamic size exclusion is the fundamental basis commonto all the GPCtheories discussed inthe next paragraphs, when models for different-shaped solutesare considered. The linear dependence of on K r / R in wide pores is of a fairly general nature It reflects a decreasing effective volume availablefor accommodation of a macromolecule in a pore. In wide pores, macromolecules have approximately the same conformations in an unrestricted volume and behave in chromatography like spherical solid particles with an equivalent radius. In fact, eq. 11 is a definition of the effective chromatographic radius of the macromolecule. It can be seen from comparing eq. 12 with the expression for the distribution coefficient of a spherical particle of radius in a slitlike poreat P < R [lo],
Chapter.4
K = l - -P R that in theprocess of chromatography in wide pores the polymer chain is like a spherical particle of an equivalent radius
Comparing the results of GPC theory for various forms ofmolecules, Casassa [9] drew a general conclusion to the effect that the equivalent chromatographic radius of an arbitrary particle is to half its mean span (the mean span being the greatest projection of the molecule onto the selected, averaged for all possible molecular orientations and conformations). The effective chromatographic radius for molecules of all typesstudied is proportional to the radius of gyration, but the coefficient of proportionality has proved to be different both forvarious forms of rigid particles [ 1 l], viz., spherical, ellipsoidal and rod-like, and for polymer molecules of various topology, i.e., linear, branched, and ring [9]. It has thus been shown that the radius of gyration is not strictly a universal chromatographic characteristic for macromolecules. Other characteristic dimensions, e.g., the Stokes radius determinable from the friction coefficient in diffusion and sedimentation processes, and the hydrodynamic radius associated withBenoit’s “universal calibration” dependence parameter [15], have also been denied the status of universal chromatographic characteristic which they are notin fact [ 101. However, in a series of molecules of certain type, any of these dimensions may be used as a characteristic chromatographic radius. Despite decades of investigations, considerable debate still exists about the proper form of the theoretical relationship among equilibriumconstant of GPC (KGpc), pore size, and macromoleculardimensions. Therefore, conversion of GPC elution volumes to some well-defined dimension isnot possible inthe sense that say the measured diffusivity leads to an equivalent Stokes radius. It is clear that the retention time in GPC bearing nonsteric interactions between the solute and the stationary phase-must depend uniquely on the dimensions ofthe solute and the stationary-phase pore. If the objects possessed simple geometry,the dependence of KGpc on pore andsolute sizes would take avery simple form; i.e.,
-
Gel
267
where R is the radius of a spherical solute and rpthe pore radius, and where X = 1, or for slab, cylindrical, or spherical pores [ 161 and Kopc is the theoretical equilibrium constant equivalent to the relative solute concentration within the pore. It is important to note that KGpc is equivalent to what others have called K,, but different from K,, which early researchers defined as the fraction of the swollengelaccessible to the solute. The situation, however, is complicated by the ill-defined and possibly nonuniform geometries of both the cavities and the solute. Attempts to convert this problem to a tractableform have taken avariety of routes, in which, of necessity, the geometry of at least one of the two components is reduced to a simple form. Laurent and. coworkers [l71 used the treatment of Ogston [l81 to model the separation as the diffusion of hard spheres of radius R through a concentrated solution of rigid rods. The result of this treatment may be expressed as
or K, = exp[ --?r l ( R
+ r,)
where r, is the rod radius (cross-sectional radius of the fibers that constitute the gel) and l is the linear concentration of rods in the gel (stationary phase). K, is the probability that a spherical particle is included in the network of the gel and is related to KGpc by the expression K, =
KGPC
vi +
h V,
where 6 is the total pore volume and V, is the volume of the gel matrix (the nonporous portion of the gel) in the column. The sum V, V, V, is the total geometric volume of the column; when this is referred to as “V,,” then K, may unfortunately appear as (V, - V,)( V, - V, ) - l , with confusing similarity to the general equation of elution volume. Ackers [ 191 avoided any precise geometric description of the stationary phase, envisaging it as a collection of semi-accessible regions, eachone having a probability of being permeatedequal to unity for all solutes below critical size, or zero, for all larger solutes. Assuming that this distribution of “pores” couldbe described viaan error function,Ackers obtained
+
K = a, i.e.,
+ b,erf
(1
-K)
+
(20)
268
Chapter 4
K =1
- erf[ ( R - a,)/b,]
(21
In a gelwith identifiable pore geometry, a, wouldbe the average pore radius, which is designatedas FP [ 191, and b, would be the standarddeviation of the pore distribution, referred to later as Ar. Note that eq. 21 is incorrect in the limit R = 0 since ,,= 1 - erf( - a,/b,). In both of the preceding treatments, the solute is considered to be spherical. Such a description oversimplifies the shape of nearly all macromolecules ofinterest. Gidding [20] took a moregeneral view of solute dimensions and analyzed the permeation of capsule-shaped rigid solutes into a stationary phase modeled as a collection of randomly intersecting planes. This treatment leadsto the result
(mR
K = exp(
(22)
where is the half of the mean projection length of the solute and is the pore surface area per unit of free volumes, i.e.,a measure of the mean pore size. For flexible chain macromolecules one must recognize the statistical nature of the solute dimensions, as represented by, for example, the mean square radius of gyration (s2). A theoretical treatment for flexible chains in cylindrical cavitiesof radius rp leads to [21]
where p, are the rootsof the equation .l,(@) = 0, .l,(/3) denoting the Bessel function of the firstkind of order zero. It may be shownthat eq. 23 predicts that a wide variety of chain macromolecules, eluted on a single column, should yield a common dependence of KGpcon the product of intrinsic viscosity and the molecular weight, [VIM R:, where R,, is frequently referred to as the hydrodynamic radius [22]. The fact that this “universal calibration” [23J has been experimentally confirmedfor numerous synthetic macromolecules has persuaded many polymer chemists to the position that R,, (less ambiguously referred to as the viscosity radius) [24] is the fundamental GPC parameter, much as empirical correlations of Kopc with the Stokes radius have convinced manyprotein chemists that R, is the controlling dimension. All of the preceding expressions have some current support among experimentalists, yet we may hardly believe that all could be consideredto be verified by experiment. We may citeuncertainties about theexperimental values rp, I , and S in theforegoing expressions as major difficulties in
-
269
Gel
validation of these models [ a ] . To some extent, it may be possibleto attribute the current state of uncertainty to the ambiguity in the solute R size . In thedevelopment of basictheory for GPCmuch lesseffort has been devoted to improve the structuraldescription of intraparticle morphology. However, computer simulations showed that the topology of the pore volume plays a significant role in determining the mass transport process. The network model [25] proposedto describe the intraparticle porous structure of a GPC column shows significant differences when compared with the results obtained using a conventional model of a parallel bundle of capillaries. This fact demonstrate the importance of including morphologicalcharacteristics into themodel to account for themass transfer restrictions.
PACKING A great variety of gels has been used or tried for GPC. They are generally polymers of varying degrees of crosslinking and usually swell in the solvents for which they are made. Examples are polydextrans for aqueous solutions and polystyrenes for nonaqueous solutions. In contrastto the general views in this matter, the swelling was found not to be essential; the permeability (or porosity) is the important factor.Aside from permeability, the rigidity o f a gel determines its usefulness in practice. Soft particles do not pack well and tend to clog columns. This means high degrees of swellingare actually undesirable. High permeability and low swelling do not contradict each other necessarily sinceit has been possibleto prepare highly crosslinkedgels of high porosity. The permeability of a heavily crosslinkedgel is built into it by the diluent which must be presentduring crosslinking. If the diluent is well matched to the gel substance, increasing the amount of it is equivalent to increasing the swelling of the gel; the network becomes more tenuous. However, whenthe composition ofthe diluent is changed, it becomes possible to make the gel more rugged that it becomes more permeablebut not more tenuous. There is a variety of commercially available packings for GPC, and others are currently under development to improve the versatility, resolution, or speed of the GPC process. For a general review of GPC packing, see Refs. 26-34.
A. Semirigid Organic Gels Most GPC .analyses of synthetic organic polymers have been made using crosslinked semirigid polystyrene gel packings. Columns packed with spherical semirigid styrene-divinylbenzene copolymers are now available in a variety of pore sizes for 15 min analyses. These gels are applicable only
-
Chapter 4
270
in nonaqueous solvents. Advances in this area have focused on improving polymerization processes for increasing particle stability toward different mobile phases. Although most high-performance packings are in the range of 10 pm, there has been some development regarding smaller size packings for higher column efficiency. Mechan et [35] evaluated mixed-bed columns, whichcontain mixtures of individual pore-size crosslinked polystyrene packings. The authors suggest that for the analysisofpolymers above 1 lo6 g/mol, 10pm particles, rather than5 pm, should be used to avoid polymer sheardegradation. In addition, the larger size packing should be employed at high temperatures ( 1oO-15OoC) for increased column life. Kulin et al. [36] described the preparation of macroporous poly(styrene-divinylbenzene) particles usinga multistep swelling process. Packings of 5 , 10, and pmwere evaluated in terms of column efficiency and resolution. Finally, the theoretical prediction that the number of theoretical plates is proportional to the squareof the particle diameter was confirmed by these authors. Spherical particlesof controlled pore size vinylacetate copolymers are also suitable for use in organic solvents. Type OR-PVAgels (Fractogel, E. Merck, EM Laboratories) are used mainly for separating synthetic polymers. Pore sizes are available to separate materials with an exclusion limit up to about lo6 dalton, but the larger pore size particles are too soft for use in high performance GPC. These small-pore size, semirigid poly(viny1 acetate) gels are stable in organic solvents such as alcohols and acetone, even at elevated temperature ( 1oOOC) but limited to maximum column pressures ofabout 300-600 psi (20-40 bar). Porous organic gels that permit the separation of water-soluble solutes are yet not as well developed as packings for use in organic solvents. However, several useful packings are available and alarger selection can be anticipated. The hydrophilic organic gels used in gel filtration are made by the copolymerization of acrylamide with the crosslinking agent, N,N-methylenebisacrylamide (Bio-GelP). By regulating the concentration of these monomers, a series of covalently bonded gel products of various average pore size isproduced. Dextrans crosslinked with epichlorohydrine (Pharmacia Fine Chemicals) are also useful for aqueous phase separations. Because of high hydroxyl group concentration in the polysaccharide chains, Sephadex is strongly hydrophilic and swells in water and electrolyte solutions. While most of these materials are relatively soft, Sephadex G-25 has sufficient strength to be used at pressure at about 150 psi for molecular weights of up to about5,000 psi.
al.
Gel
271
A detailed study of Sepadex-75 was presented by Drevin et al. [37]. These authors studied the effect of mobile phasepH and ionic strength on the elution behavior of protein with different isoelectric point values. Sephadex LH-20 is a semirigid gel prepared by the propylation of Sephadex G-25. This gel is used with polar organic solvents (e.g., alcohols, tetrahydrofuran), but is also compatible with water.It is applied in a relativelywideparticlerange(25-100pm);however,narrowerparticle-size fractions (e.g., 25-30 pm) can be obtained by sizing to improve column performance. Hydrogel packings produced by Waters Associates also may be useful in GPC. These water-wettable beads are made from highly sulfonated, crosslinked polystyrene. Because ofthe surface sulfonic acid groups, ionic sorption effects may occur on either side of pH 7 in aqueous media, thus limiting mobile-phase solute compatibility. To overcome the poormechanical properties dextran gels, Tixier et al. [38] prepared mixed polyacrylamide-agarose gels in bead form. Four types of gel, developed by 1’Industrie Biologique Francaise, are available as Ultragel ACA-22, ACA-34, ACA-44, and ACA-54 from LKB. These gels differonlyincomponentconcentration, the firstdigitrepresenting the percentage of polyacrylamide and the second the percentage of agarose. Crosslinked poly(acryloy1 morpholine) (EnzacryP Gel) was prepared in bead form by copolymerization of acryloyl morpholine and N,N‘- methylene-diacrylamide in aqueous solution. This support contains few protons that are sufficiently labile to exchange with eluting solvent. In this respect it differs from other universal GPC matrices and from other water-compatible packings suchas crosslinked dextran and crosslinked polyacrylamide [39]. SpheronO is a macroporous, hydrophilic column packing originally developed at the Institute of Macromolecular Chemistry in Prague [40]. The packing is prepared in bead form by suspension copolymerization of hydroxyethyl methacrylateand ethylene glycol dimethacrylate.The pendant hydroxyl groups of Spheron gel permits chemical modification to be made. Consequently,Spheronderivativeswithspecificpropertiesmaybe obtained. These include: Spheron C, Spheron S, Spheron DEAE, Spheron ArA, and Spheron Oxine. Owing to the high content of the crosslinking agent, Spheron gel exhibits minimum swelling.Its rigidity is sufficiently highto permit its use at high flow ratesand high pressures( <200 atm) without dangerof particle cracking or deformation. On columns packed with unmodified Spheron, various substances may be separated by gel filtration according to their molecular dimensions. The lower limit of the fractionation range is about the same for all types Spheron gels-approximately 3,000 Daltons. The upper limit dependson the type of gel.
272
Chapter 4
Spheron gels may be usedboth in aqueous and nonaqueous media. In aqueous media Spheron gelsmaybeusedin analytical and preparative separations of polysaccharides, nucleicacids, and some proteins according to their molecular size.The use of Spheron in organic solvents hasa limited area of applications. A review of hydrophilic polymeric packings for biopolymers was written by Makino and Hatano [41]. Hirayama and Ihara [42] discussed the polymerization chemistry involved in the production of hydrophilic packings. Meehan etal. [43] evaluated Aquagel packings, that consist of polyhydroxy and polyacrylamide surfaces. Universal calibration, which was found to hold with these packings, was used for the analysis ofpoly(viny1 alcohol). The evaluation of macroporous glycidylmethacrylate-ethylenedimethacrylate copolymers was reported by Tennikova et al. [44]Hirayama and coworkers[45]described the preparation of poly(u-methyl-L-glutamate) packings for size exclusionchromatography. A glucomannan packing was prepared and evaluated by Morita and colleagues [46,47]. Several patents were awarded for a cellulose packing and for preparation of a GPC support by suspension polymerization of acrylonitrile with a divinyl monomer [49]. Finally crosslinked hemicellulose (xylan), called xylogel, was evaluatedas a GPCpacking [501.
B. Inorganic Packings Vaughan [51] was the firstto recognize that porous glass would be a good column support for GPC but his packings proved to have pores which were too large or too small for satisfactory fractionation. Haller [52-541 developed a controlled method for preparing glass with uniform pore size. The first satisfactory separations of high polymers in organic media with porous glass were demonstrated by Moore and Arrington [55]. Apart from porous glass particles, which tend to be irregular in shape, the other widely used inorganic packings are spherical silica beads marketed under tradenames Porasil and Spherosil. The use of these supports in GPC separations of polymers in organic media was first described by de Vries, Le Page, Beau, and Guillemin [ 56-58]. Porous silicabeads manufactured by Rhone-Poulenc (France) are distributed by Water Associates in the United States. These untreated siliceous particles can beused for preparative work with either organic or aqueous mobile phases at elevated temperatures. Porasils are also offered in a deactivated form in the Porasil-X series. The deactivation is a chemical treatment that decreases, but does not eliminate, alladsorption problems.
Chromatography Gel Permeation
2 73
Inorganic packings may be used withboth organic and aqueous mobile phases. Some particles are untreated, others have been modified by adding organic functionalityto reduce adsorption. However, with aqueous systems, appropriate additives may be requiredto eliminate solute adsorption [ 5 9 ] . LiChrospher -totally porous spherical silica microparticles with a range of pore size-is manufactured by E. Merck. These microparticles have a relatively large internal porosity that provides both good sample capacity and column efficiencies[601. Gel Type SI is an irregularly shaped, untreated porous silica, also manufactured by E. Merck. It was originally designed for general use in conventional adsorption, gel permeation, and partition chromatography. However, because of its availability in relatively small particle size, it can beutilizedinhighperformance GPC for some operations and maybe particularly suitedfor preparative GPC. Columns of very high efficiency silica SE packings are available from E. I. du Pont de Nemours and Co. These spherical particles are untreated porous silica witha range of narrow-distributionpore sizes. du Pont SE-60 poroussilicamicrophaseshavebeenespeciallydesigned for separating small molecules daltons). Another series of these high-efficiency particles (Zorbax PSM) have been developed for specific applications in GPC. This packing is available inboth untreated or silanized form, for use in aqueous and organic mobile phases, respectively. Vit-X packings (Perkin-ElmerCorp.) are irregular porous silica particles, deactivatedto reduce adsorptive properties. Siliceous particles which have been surface-modified by adding organic functionalityto reduce adsorptive properties have created great interest. Silanol groups on the surface of untreated porous silica packings can cause problems in GPC separations by adsorbing the solute. This biases the desired size-exclusion mechanism,and the desired relationship between retention volume and molecular size will not be obtained. Mixed retention usually is evidenced by tailing chromatographic peaks, lowered column efficiency, and, in extreme cases, retention beyond the total permeation volumes. Fortunately, silica surfaces can be altered by adding certain organic functional groups to effectively eliminate this disadvantagefor most applications. By proper selection of organic functionality, the surface of particles can be alteredfor both organic and aqueous mobile phase applications. One approach used to eliminate solute adsorption in organic solvents is to maximize conversion of surface silanol groups on silica to their trimethylsilyl derivatives [61-631. This hydrocarbon-modified packing can be
Chapter 4
274
I
i-OH
+ C1Si(CH3),
A “HC1
- i-0-Si(CH,),
I
(25)
Unreacted silanol groups (which constitute about one-half of the totalsilano1 concentration) become shielded by an “umbrella” of tightly packed trimethylsilyl organic groups. As long as the trimethylsilyl groups are at a sufficiently high concentration on the surface (>3.5 pmole/m2), the residual silanolgroups remain unavailable for unwanted adsorptive interactions. Reactionof surface Si-OH groups with chlorosilane reagents to high yields is promoted by using a large excess of reactant, conducting the reaction in the neat liquid reactant or in a dry solvent, mechanically removing the volatile reaction product during the reaction (e.g., volatilization) [ M ] or by usingan appropriateacid acceptor such as pyridine [65]. If desired, untreated silica packing may be silanizedin situ in a reaction with chlorotrimethylsilane [66]. This approach is useful to resilanize a set of columns that have become somewhat adsorbing because of loss of deactivating bondedorganic groups. An improved mediumfor high pressuregel filtration was prepared by Lee and Jarrett [67], by derivatization of aminopropyl silica with glucose. The reaction involved was likely Schiff‘s base formation between the aldehyde of glucose and the amine of silica which was then reduced with NaCNBH,. This glucose-silica behaved as a nearly ideal molecular sieving support for thehigh pressuregel filtration chromatography of proteins and is superior in performance to many currently available supports. p-Bondage1 (Waters Associates) is a porous silica to which an ether functionality has been chemically bonded. This material is offered in four pore-size columns, plus an E-linear column that is a blend of pore sizes. The manufacturer states that these packings are compatible with solvents all polarity from n-heptane to buffered aqueous mobile phases; however, there is the usual pH limitations of 2-8.
-
Gel Permeation Chromatography
275
CALIBRATION In view of applying GPC to polymeric and oligomeric mixtureseparations, it is, nevertheless, necessary to know the mode of transformation the GPC elution curve in valuableinformation concerning the true composition of a certain mixture. This will enable us to offer a quantitative interpretation of the GPC results. However, one important problem is that GPC is a relative method and the quantitative interpretation is based on the validity calibration. The requirement for calibration arises in part from the absence of a complete theory for GPC, which would exactly define the relationship between the macromolecular dimensions of the solute and the experimentally measurable chromatographic partition coefficient K G p c .
where V, is the retention volume the solute, V, the interstitial volume (obtained experimentally as the elution volume of a solute too big to enter the pores), and V, the total volume of liquid in the column, equal to the sum of V, and the pore volume. K G p c thus represents the fraction of the pore volume accessible to the solute and ranges from zero to unity. However, one important problem is that the interpretation ofgel chromatograms and especially determination of the molecular weight the species separated needs a proper calibration curve. Since there are many solute-solvent systems involvedin GPC as well as many types of different pore sizes, the best way to obtain an accurate calibration is by experiment rather than by theoretical calculations. Errors in the calibration methods are minimized by obtaining a calibration curve under the same conditions as the sample separation. The calibration curve for a set of columns can be established experimentally by relating the peak elution volume to molecular weight for a seriesof narrow molecularweight distribution (MWD) standards. This is co-called direct calibration method with narrow MWD standards, The accuracy of this method depends on whether the reference compounds and analyzed sample all have a similar conformation and chemical structure. Gel chromatogram determination of each standard compound, plotting of the calibration curve, and their comparison represent the main steps of the GPC calibration by the direct method. The main disadvantage the direct calibration method is the lack of narrow standards. Polystyrene and a few other polymers are theonly polymers for which a series commercial standards of different molecular weight and narrow MWD is available. The calibration curve may be represented by the following equation
276
Chapter 4
where V,, is retention volume and A,B are constants. In the case of oligomers, the direct calibration method was applied using as standards well-defined substances with known molecular weight. Alkanes have been considered as potential standards in the calibration of GPC separation of oligomers. The absence of solute-solvent interactions and molecular associationssupport this idea. Universal calibration proceduresrepresent a tentative calibration associated with the determination of a rigorous way to transform the gel chromatogram into a true molecular weight distribution of the analyzed sample. The Q factor [68,69] and hydrodynamic volume [70,71] are the major parameters for universal calibration procedures. The Q factor is the ratio ofthe molecular weightto the extended chain length calculated from bond lengths and valenceangles. Its application assumes a very extended molecule along with the existence of a certain dependence between the "length of the molecular weight" and VEL.This typical length, expressed in angstroms ), yields the molecular weight of a linear polymer by means of an appropriatelinearity factor Q:
(A
M = QA
(28)
In this case, the universal calibration curve is based on therelationship VEL
=f(h3
A)
(29)
This dependenceis subsequently consideredto be independent of the nature and composition of the solvent-nonsolvent system. Applicable only to rigid polymers, the Q factor led to erroneous results in the fieldofflexible macromolecules [72]. The coil conformation adopted by macromolecules in solution suggested the idea of utilizingthe hydrodynamic volume asa universal calibration parameter in GPC. The universal calibration procedure utilizes the concept of the hydrodynamic volume of the solute molecule [73,74]. Hydrodynamic size of macromolecule R
=
(1M[rll)*"
is a universal characteristic of all macromolecules and solvents uniquely determining the retention time of macromolecules in a chromatographic experiment. The opinion of Russian scientists Vilenchik et al. [75] is that the all attempts to choose another universal characteristic have failed just because only the R value takes into account both the average size of the macromolecules and the density of the macromolecular coil as well as its partial draining determined by the value of the hydrodynamic interaction
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277
between the segments. It is precisely thesefactors that determine the behavior of macromolecules in the GPC process. In general, GPC calibration curves for solutesofdifferenttypesmerge into a singleplotwhen the calibration data are plotted as log [VIMvs elution volume instead of the usual logMvs. elution volume. The universal calibration method is conceptuallysound, but its use is still rather limited. However, with increased use GPC of viscometric detectors, therehasbeen a great deal of interest regarding the validity and application of universal calibration [76-841. Sanayei and O’Driscoll established universal calibration for polystyrene and poly(methy1 methacrylate) standards. Intrinsic viscosity of the oligomers of these polymers were estimated by extrapolation of the MarkHouwink equation, and these data were used to extend the universal calibration to the low molecular weight region. Using chromatographic analysis and viscometric investigations, it has been shown by Vilenchik et al. [75] that the linear relationship of the log [V]and log M of flexible chain macromolecules exhibits a break on passing from the oligomeric to the polymeric range. Simultaneously, the Huggins constant also changes [86]. These changes result from a decrease in the draining of macromolecules with increasing number of statistical segments. In particular, draining affects the hydrodynamic dimensions determiningthe GPC behavior of macromolecules. In themolecular weight range lower than l o 4 daltons, the Gauss statistic is no longer applicable [87-911. Actually, it is known that a viscosity theory, basedon the fact that the solute has molecular dimensions considerably higher than those of the solvent, cannot represent a valuable tool of viscosity determination for systems of particles having comparable dimensions. This has been observed since1958, when negative values of intrinsic viscosities werefound with certain oligomeric solutions[92]. Also with the same occasion, attention has been drawn [92] to the fact that, in the absence of irreversible adsorption phenomena, universal calibration may be employedwithsatisfactoryresults,even in the caseoflowmolecular weights, if the solutes do not have aromatic nuclei in its structure. Most failures of universal calibration are normally due to the failure of the size exclusion mechanism [93-971. In explaining the separation in GPC itis usually assumedthat thermodynamic equilibrium existsin solute distribution between the mobile and the gel phases in the column. On the other hand, the solute separation in GPC is mainly a result of steric exclusion from the gel pores. In fact the pure “size effect” is rarely encountered and thesolute separation is affected by other secondary mechanisms. These stem mainly from molecular interactions among solute, solvent, and gel in the column. Since 1981, Berek pointed out that both secondary effects,
Chapter 4
278
adsorption, and thermodynamic partition of the solute, usually represent only additional effects on thepredominating mechanism of steric exclusion [98]. However, theseeffects have to be taken into account, e.g., by employing the universal calibration concept for polymers in eluents with different thermodynamic quality and adsorptionstrength of the gel [99-1051. Under certain circumstances, the secondary effects may predominate over the basic mechanism of steric exclusion, as, e.g., in the case of the total retardationof the solute in the column as a consequence ofits adsorption on the gel. Anomalies in the application of the universal calibration method have also been noted [ 106,1071. Dubin and Principi [ 1081 have proposed that deviation from [q]-M correlations are only correct at infinite dilution. This approach appears to be marginally superior to the straightforward [TIM calibration for polymers havingdifferent conformations. The observed anomalies with universal calibration are of three types [109]: The unexpectedly large elution volumes determined by irreversible adsorption The deviation specific to systems oligomer-poor solvents The elution order in the domain of small molecules or oligomers not being governed only by the size of the solute particle GPC data in the domain ofoligomers and smallmoleculeshave pointed out the extra mechanisms involved inseparation [ 110-1 161. Besides the size exclusioneffect, in the GPC of oligomers, these secondary mechanisms are the solvation of solute species, the adsorption on thepore walls of the packing, and, for swelling packings, the partition between the gel and the whole phase. Tsitsilianis et al. [ 1171 tried to overcome the above problems by proposing another universal calibration procedure which can be applied to the low-molecular weight region.In order to obtain amore accurate value ofM at low molecular weights from the intrinsic viscosity, the following relation between [ T ] and M has been proposed[ 1181: [7)]-1
=
+ AIM-
(31)
where A, and are constants for a polymer-solvent system at a given temperature. This empirical linear relation for [v] versus M”” provides excellent fits of data in the molecular weight range 1,000-100,OOO[118, 1191. We now turn to theso-called universal calibration curve suggested by Benoit which is representedby the equation [71]
Gel
279
where [v]is the intrinsic viscosity of the polymer. Eq. is valid for agreat numberof polymers withdifferent chemical composition and molecular structures. In aparticular chromatographic tem of a given set of columns with temperature and solvent specified, all the polymers with a given VELhave the same hydrodynamic volume[?]M, and consequently we may write
where the subscriptsp and S refer, respectively, to the polymer to be characterized and to a standardsample of another polymer. Obtaining [v]from thewell-known Mark-Houwink-Sakurada (MHS) empirical relation for bothpolymers
and rearranging we obtain [
K, log M, = -log K,
+
+ ++ a, log M,
Eq. can be used to obtain the calibrationcurve for the polymer p from the calibration curve ofstandards of another polymer if the MHS constants for bothpolymers are known [ Substituting [v]from eq. for thepolymer p and standardS into eq. and rearranging results in the following relation:
where
where AI,, Air, A,, and A, are the constants of eq. for the polymer standard andpolymer under analysis, respectively. Knowingthe calibration curve logM, = f(V,,) of the polymer standard it is possible, using eq. to obtain the molecular weight of the polymer p which corresponds to the molecular weight M, of the standard giving the same retention volume VEL.
Chapter 4
280
A. Calibration with Broad Molecular Weight Distribution Standards
Since narrow-molecular weight distribution standards are available only for polystyrene, broad-MWD polymer standards areused for GPCcalibration. There are two different ways of using these standards, the integral MWD method and the linear calibration method. The first method utilizes the complete MWD curve of polymer standards and the second method uses only the average molecularweight values of polymerstandards butassumes a linear approximation of the GPC calibration curve. Both methods are valid and useful at times, dependingon GPCconditions. The accuracy of the broad-standards calibrationmethods varies, depending on the accuracy of the available MWD information on the standards and theaccuracy ofthe linear-calibration approximation [121-1271. When the separation columns are purposely selected to assure linearity in calibration, theuse of linear calibration methods is definitely recommended overintegral MWD methods. Unlike those narrow-standards methods, the calibration curves obtained by broad-standards methods are affected by instrumental peak broadening. Without corrections, this calibration errorcan cause errors in molecular weight analyses of polymer samples. The integral MWD calibration method requires that the complete MWD of the broadpolymer sample intendedfor a calibration standard was fractionated by a classical method and themolecular weight determined for each of the fractions. The MWD information obtained in this way for the whole polymer, now the calibration standard, was then used to establish the GPC calibrationcurve. This experimental polymer fractionation approach has not generally been followed in practice because of the tedious nature and the questionable molecular weight precision of the experimental fractionation and the molecular weightsof the characterized fractions. A practical alternative approach suggested by Weiss[ 128 makes use of theoretical polymer MWD and average molecular weight values to provide the needed MWD information for theintegral-MWD calibration. This approach has been applied to both water-soluble polymers [l291 and organic soluble polymers[ 1301. Using this calibrationmethod, Bezdadea and Uglea [l221 analyzed poly(viny1 acetate) obtained by matrix polymerization. With this occasion, the formation of “replica” type macromolecules and “inclusion” type oligomers was evidenced. The presumed advantage of the integral method is that it makes no assumptions regarding the calibration curve shape and thus permits an accurate search for nonlinear calibration curves. However, this advantage
Gel
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often does not occur in practice, owing to the rather poor precision of the method. The linear calibration method using broad polymer standards are proposed by Hamielec [ 13 l] and developed by Yau [ 1321 and others [ 1331351. The Hamielec method [ 1311 consists of a search for an “effective” linear calibration and offers truly a practical way of obtaining GPC calibration curves that are specific to polymer type. The method needs only one broad-MWD standard of the same structure as the unknown samples. This can usually be providedeither by commercial standards or by converting of the samples into a working standard through independent determinations of its values of 2,and M,, using, for example, lightscattering and osmotic pressure techniques. Although a single broad standardis often used, the Hamielec method can be also used with two different molecular weightstandards, as long as there are two average molecular weight values known.The precision of the method increases with the difference between the two molecular weight values usedin calibration. In addition todependence on theaccuracy of the linear calibration approximation and on the experimental M, and M,,values of the standard, the Hamielec method has two other weaknesses: the physical significance of the effective calibration curve is not defined, and the calculated molecularweight values are accurate only for samples having a GPC elution curve similarto thatof the standard. In an improved version of the Hamielec method, GPC V2 [ 1321,compensation is provided for the symmetrical peak broadening caused by columndispersion effects. A more sophisticated versionof the Hamielec method, GPC V3 [135],includes a consideration of the skewness of the GPC column dispersion. In contrast to the integral MWD method, linear calibration methods pose no restrictions on the MWD shape of the standard. In practice, linear calibration methods provide a much better compromise than does the integral MWD method, because the linearity of the GPC calibration curve can be improved by the proper selection of GPC columns. For GPC columns with nonlinear calibration curves, a modified broad standardmethod must be used for which the linear calibration approximation is not assumed. In the last fewyearsmany attempts havebeenmadein order to develop new calibration methods using broad-MWDstandards [ 136-1461.
V. BANDBROADENING In spite of the efforts dedicated to the explanation of the GPC behavior of low molecular and macromolecular substances, there are still unanswered
282
Chapter 4
questions. One of themis the explanation of the coexistence of tendency of separating species when a mixture passes through the column, and that of broadening the peak, when the analyzed sample contains one molecular species. In column chromatography, a small volumeof the sample solution is injected to form a band at the top of the column. As this band migrates downstream, its width increases. Band broadening of a pure component can be used to measure the efficiency of the chromatographic system. The nomenclature used in reporting chromatographic band broadening in the literature is quite varied and sometimesconfusing.Readers should be aware of the many near synonyms for band broadening that appear in the literature, such as peak broadening, zone spreading, and instrumental, axial, longitudinal, or column dispersion. All forms of band broadening are detrimental to chromatographic separation. Basically, chromatographic separation is a demixing phenomenon and band broadening is a back-mixing or remixing phenomenon. Excessive peak broadening can result from poorly packed columns and can also result from excessive extracolumn volume that is present in the chromatographic instrument. An understanding of the basic column dispersion processes in wellplanned GPC equipment using a well-packed GPC column is needed for making efficient GPC separations with the best compromises among time, accuracy, effort, andconvenience. There are three fundamental processes leading to band broadening in GPC separation. The first is eddy diffusion that arisesbecausesample molecules take separateroutes through thepacked bed. The second contribution to band broadening occurs as a result of the resistance of solute to mobile phase masstransfer. This broadening process is caused bythe velocity gradient profile that exists in a single flow stream. Since liquid nearthe surface of the column packing particle moves relatively more slowly than the liquid at the center of the stream, solute molecules at the center migrate farther downstream than the others. Band broadening due to this dispersion process decreases with increasing lateral diffusion rate of the solute molecules between the fast- and the slow-moving liquid regions. At times this dispersion process is called “mobile-phase lateral diffusion” or “extra-particlemass transfer”. Longitudinal diffusion is the third basic band-broadening process in which the band is broadened along the column parallel to the flow direction by molecular diffusion of the solute. This form of band dispersion is important in gas chromatography but is insignificant in large-molecule GPC because of slowdiffusion. There are two ways of approaching the theoretical interpretation of
Gel
283
chromatographic band broadening. In the kinetic or rate theory[ 1471 band broadening is explained in terms of realistic models involving molecular diffusion and flow mixing. In developing a rate theory, differential equations are derived to describe solute mass balance in a differential column section. The four classical, independent mass transfer process are considered in their partial differential form: longitudinal diffusion (D,&,/ax), eddy diffusion (DEaC,/ax), stationary mass transfer (D,dCJar) and mobile phase lateral diffusion (D,&3C,/ay),where is the column length variable along the column axis, y the distance variable in the lateral direction, and C, and CSthe solute concentrations in the mobile and the stationary phase, respectively. The quantity DEis the eddy-diffusion coefficient that is expectedto be proportional to dp(particle diameter of the packing) and v (flow velocity)[ 1471. A rate theory for GPCdispersion employsthe following partial differential equations. For stationary mass transfer (permeation)
where r is the radial distance from the center of the spherical porous particle. For mobile-phase masstransfer,
ac,
ac,
-++"DD,,~= at ax
a",
-uDsM
(x) acS r dp/2 =
+
where U = 6(1 - +)/dp+, with being the volume fraction of the extra particle solvent volume.For boundary conditions, at r = dJ2,
In these expressions, coupling of eddy diffusion to mobile-phase transfer and longitudinal diffusion effects are neglected.These assumptions are appropriate for GPC,since overall mobile-phase dispersion is usually small compared to permeation. Although the complete solution of these differential equations (eqs. 37 and 38) under the specific boundary conditions is not known, an approximate solution can be obtained for a limiting case where near-equilibrium solute distribution exists betweenthe phases. This limiting condition closely approximates most GPC experiments and predicts a near-Gaussian elution peak shape. The second theory on band broadening, which is a simplified, phenomenological approach, is the plate theory [ 1481. It explains band broadening by random fluctuations around the mean retention volume bya simulated partitioning model in a chromatographic column. The plate theory
Chapter 4
284
was first applied to liquid chromatographic studies by Martin and Synge [ 148 Because of its simplicity, the plate theorywill continue to be a useful, general model for studying chromatographic band broadening. The basic derivation of the general plate theory can be found in many GC and LC books [ 149,1501, and only a brief explanation is given below. In the plate model the chromatographic column is pictured as being divided into N number of adjoining separation zones, with each zone having such a length that there can be complete equilibrium the solute betwen the mobile and the stationary phases within the zone. Each zone is called a “theoretical plate,” and its length in the column is called “high equivalent to a theoretical plate,” HEPT, orsimply the “plate length,”H. To illustrate the plate concept, a primitive five-plate column( N = 5) is shown in Fig. 2, where the sequence the plates is indexed bythe serial number r. The figure shows values between q and p , which are thefractions of the total solute in mobile and stationary phases, respectively, with q p = 1. In this picture the flow of the carrier liquid is simulated by the sequential displacement ofthe entire top mobile phase sectionto the right, one plate at a time. The number of timesthat this volume displacement has taken place followingthe introduction of the sharp band into the first place is designated bythe index number n. With each volume displacement, only a fraction q of the solute in each plateis carried to the next plate, leavinga fraction p behind. The solute in each plate reequilibrates inthe new situation, and the displacement process repeats. This repetitive partition process leads to a solute distribution among many neighboring plates that follows the binomial distribution function. According to binomial statistics, the fraction of the original solute being in the rth plate following n displacements is
+
=
n! 4%”” r!(n- r)!
liquid
stationary
phase
0
1
2
4
Plate
Figure 2 Hypotheticalcolumn 151.)
fivetheoreticalplates.(AdaptedfromRef.
Gel
285
In chromatography the solute concentration detector monitors the fraction q of the Nth (last) plate as a function of n. The elution curve is therefore described by q W(n,N),where n is proportional to elution volume. For the usual large number of plates in chromatographic columns ( N > 50),
the binomial solute distribution becomes indistinguishablefrom the Gaussian distribution curve [ 1511. With algebraic transformation, the Gaussian peak elution profile as predicted by the plate model can be expressed in terms ofthe experimental quantities of concentration (C), retention volume (V), peak retention volume ( V,), sample weight W , and p , the fraction of solute in the stationary phase:
By comparing eq. 41 with the general Gaussianfunction
where is the area of the peak, the standard deviation of the Gaussian peak in retention volume units, and h, V, and V, are as defined in the following equations:
i
where is the standarddeviation of a general statistical distribution, Vand the retention volume variables, V, the retention volume ofthe chromatographic peak, and the subscript i is the sequence index for the discrete equally spaceddata points used in the variance calculation:
p approaches unity
Chapter 4
286
Other results ofthe general plate theoryare
where L is column length. In summary, the predictions resulting from the general plate theory are 1. Gaussian peak shape (eq. 41). 2. Peak width increases linearly with retention volume (eq. 46).
Each peak in a chromatogram has approximately the same value of N and H (eq. 46). 4. Nincreases linearly with column length (eq.47). Items 2 and of these predictionsare notobserved inGPC. The GPC columns has many unique features. Whilethe volume of the solvent inside the porous packing does not affect solute selectivity in otherLC methods, it in fact serves as the stationary phase in GPC, in the sense that it causes the differential elution of solutes. Accordingly, while this liquid volume is described as thestagnant mobile phasein general LC discussions, it is called the stationary phase in GPC. This subtle difference in basic concept has caused much confusionand many inconsistencies betweenGPC and general LC terminology. Thus a classification of band broadening terminology is presented hereprior to the discussion ofthe GPC band broadening mechanism. The meaning of the phrase “stationary phase masstransfer” is different when used in GPC versus general LC discussions. Historically, all LC dispersion processes were considered as being independent of each other. Although the magnitude and the relative importance of each plate height contribution from various dispersion mechanisms vary from one form of LC to another, the overall plate height is given by
where HL, HsM, H,, and HMare the plate height contributionsdue to longitudinal-diffusion, stationary-mobile-phase, stationary phase, and interparticle-mobile phase transfer processes, respectively. The phrase “stationary phase mass transfer’’ means the H,,,,, term in GPC, but.the Hs term in other LC methods. In a classical sense the LC stationary term H, defines the dispersion effect of a distinct, separate LC stationary phase, but does not at all apply to GPC separations involving nonsorptive packings. In GPC the concern is the HsMterm, called the stagnant-mobile phase dispersion in LC discussions. Since the phrase “stagnant mobile phase” is somewhat
Gel
287
confusing in GPCdiscussions, HSM was called simply the “stationary phase” by Yau [ 1521. With regardto band broadening in GPC, the plate height contribution due to longitudinal diffusion HL is insignificantly small because the large solute molecules commonly encounteredin GPC have very small diffusion coefficients. With HLand H, dropped from eq. 48, we have for GPC
H = HSM
+ HM
(49)
Besides the difficulties encountered when utilizing GPC for theseparation of small moleculesor oligomers, this method also has some intrinsic disadvantages, compared to theother chromatographic methods. Thus, mention must be made, among others, of the low value of peak capacity, n. This term is defined as the maximum number of peaks that can be resolved within a specified range of elution volume. In turn, the V, of a species is limited to the accessiblevolumeof the pores for the givenspecies. pointed out by Giddings[ 1531, GPC is uniquein that there isa well-defined limit to peak capacity. The concept of the theoretical plate is usedto compare the separation efficiency of columns. pointed out by Cazes[l541 The theoretical plate concept is borrowed from that area of chemical engineering involving fractional distillation. A theoretical plate, in the caseof distillation, refers to a discrete distillation stage constituting a simple distillation in which complete equilibrium is established between the liquid and vapor phases. In the caseGPC of where the two phasesare in constant motion, i.e., the solvent in the interstitial volume and the solvent within the gel pores, equilibrium is probably never achieved. The true significanceof the theoretical plate is lost. It must be realized, moreover, that the calculated theoretical plate in a chromatographic column represents a smaller separating ability than the theoretical plate in a distillation columnby a factorof twenty-fiveto fifty. Then, the determination of N in GPC is more a measure of how well a column is packed,that is, how much peak spreading it will cause, than how well it will resolve. Moreover,the method of determinationof N in the case of GPC is questionable. Whena solute of low molecular weight is used and its VELvalue, introduced in the relation N = 16
($)
2
where W represents the peak base width, is determined, the value of N thus obtained is meaningless, if referring to a GPC column, due to the fact that the gel is wholly accessible to the reference sample (employed for the determination of N) and partially accessible to the species forming the
Chapter 4
288
mixture subjectedto analysis. It is obviousthat in the case of an oligomeric or macromolecular mixture to be passed through the GPC columns, the support will offer a higher number of theoretical plates for smaller molecular species than forthose of higher molecular weight [ In addition, severalapproximations,althoughheuristicallyuseful, tend to propagate an ideal view which is longer validand which tend to induce overconfidencein the potential ofGPC. The assumption ofa perfect linearity of calibration curve, the use of the term “Gaussian”to qualify the shape of the gel chromatogram (this adjective implies morethan thesimple notion of symmetry), and the poor definition of the baseline (especially in the case of oligomer characterization)due to uncertain limitsof integration and thesignal-to-noise ratio are examples of excessive idealization or inadequate interpretation of GPC data. Although lacking a suitable theoretical base for a precise method of estimating its results, the GPC remains one of the most frequently used methods in the characterization of oligomeric mixtures, especially for a qualitative appreciation ofthe mixture composition[
VI.
NON-SIZEEXCLUSION EFFECTS
Flow Rate Effect If the equilibrium assumption in GPC is valid, then the elution volume should be independent of flow rate. The majority of earlier workers concluded that elution volumes were independent of flowrate within the usual flow rate ranges [ However, a number of studies have shown that elution volumes can either increase or decrease with flow rate, depending upon the experimental conditions [ Some of these observations have been rationalized, but others remain unexplained. Some ofthe possible explanations for these observations of flow rate dependent elution volumes include nonequilibrium effects, molecular structure changes with flow rate, stationary-phase changes with flowrate, and concentration/flow rate effects. Nonequilibrium effects in GPC can occur in two ways. The first is when equilibrium is not maintained at the micropore mouth between the solution in the interstitial volume and the solution within the micropore. The second is when equilibrium is maintained at the micropore mouth but the solution in the interior of the micropore is not at equilibrium with the solution in the interstitial volume. In this case diffusion of the solute into the micropore could beimportant [ At low flow ratesthe elution curve is Gaussian in shape, and therefore symmetrical, and the peak position is equalto the first moment. At higher flow rates, however, the elution curve can become skewed whenthe diffu-
Gel
289
sion rate into micropores is sufficiently slow. Ifthe first moment is independent of flow rate, as predicted by Herman's theory, and the elution curve becomes more skewed with increasing flowrate, then the peak position of the elution curve should decrease as the flow rate increases. Hence, when observing flow rate dependent elution volumes, one must be careful to measure the position ofthe first moment,rather than the peak position. Molecular Degradation. A number of experimenters have demonstrated that high molecular weight molecules can be degraded in a chromatographic column at high flow rates[ 164-1661. These studies have involved a number of different polymers and a number of different instruments. Molecular degradation with increasing flow rate results in an apparent increase in elution volumes with increasing flow rates. Configurational Changes. The flowfield through packedcolumnsbelongs to a class of flows referred to as kinematically nonhomogeneous, meaning that the strength of the velocity gradient variesfrom point to point within the flow field. Macromoleculesare subject to gross configurational distortion depending on the strength of the local velocity gradientthat they experience. Severalauthors [ 167-1721 have speculatedthat, in nonhomogeneous flows, the lowest velocity gradient regions of the flow can become enriched in polymer concentration asthe macromolecules attempt to minimize configurationalentropy by escapingthe elongating effects the high velocity gradient regions.The quantitative aspects of this effect exist [ 1691, although many experiments indirectly support the idea. In any nonhomogeneous flow, macromolecules do not move with the local solvent velocity, leading againto the possibility ofa nonuniform spatial concentration distribution [ 1681. Purely hydrodynamic arguments are sufficient to show this, with no ad hoc thermodynamic assumptions as above. Cross-streamline migration is predicted towardthe concave side when the local velocity field is curvilinear and nonhomogenous. Clearly, the opportunity for both these modes of migration, thermodynamic and hydrodynamic, exists in principle in the flow through chromatographic columns. Maximum velocity gradient regions, of magnitude 100 to 1,OOO sec" under reasonable operating conditions, exist in close proximity to stagnant, low velocity gradient regions. Macromolecules travel curved paths in circumnavigating the packing particles. Thus it is likelythat nonuniform concentration profiles may arise from thefluid mechanicsin chromatographic columns. When macromoleculesare subject to large rates ofdeformation, their configuration can change by stretching and aligning with the flow streamlines [ 1701. Such a situation can occur at sufficiently high flow rates in a
290
Chapter 4
chromatographic column. Some workers have suggested that this could change the partition coefficient of the macromolecule and,. therefore, its elution volume could change with flow rate. These workers have concluded, however, that this effectis of no significance in GPC [ 171,1721. Flow Rate. A possibility exists that flow rate dependent elution volumes could arise from changes inthe pore volume or pore size with a change in flow rate and a corresponding change in the column’s pressure drop. Either of these effects would result in the elution volume decreasingas the flow rate increases. This isa possible mechanism of flow rate dependent elution volumes in columns packed with nonrigid packings [l731 although most authors have concluded that this is not a significant effect in the range of flow rates and pressure drops typically used in GPC [ 1741. Stationary Phase Changes
B. Concentration Effect Elution volumes have been observedto increase as thesolute concentration is increased [ 175-1771 and also as the volume injected is increased [ 1731. These observations suggest that, if equilibrium is maintained at the pore mouth, then the equilibrium partition coefficient must increase with increasingsoluteconcentration.Such an effecthasbeenexperimentally shown to be true for bothrigid and flexible macromolecules. Concentration effects, i.e., the dependence ofthe elution volumeand of the width of the elution curve on concentration and overall amount of injected polymer solution in GPC havebeenobserved in many works. Waters [ 1781 supposed the increase in elution volume with increasing concentration to be due to the higher viscosity ofthe injected solution. Boni et al. [179,180] observed that the change in elution volume with a change in concentration was a linear function of the logarithm of molecular weight or of intrinsic viscosity. In the latter case, they obtained a single linear dependence for variouspolymers.SimilarresultswereobtainedbyLambert [ 1811. The hypothesis of viscosity phenomena was supported by Goetze et al. [ 1821, who injecteda polymer solution ina solvent whose relative viscosity was higher than that of the solvent used asthe mobile phase. According to them, viscosity phenomena causea change in the elution volume, but the whole change cannot be assigned to these phenomena. Moore [l831 explained the viscosity phenomenaas “viscous fingering.” Ouanc [ 1841 stressed the effect of overloading of the column in the injection of solutions of mixtures ofstandard polymers having different molecular weights and high concentrations. Rudin [ 185-1871 showed that the effective hydrodynamic volume of macromolecules in solution decreased with increasing concentra-
Gel
291
tion and that this effect mustbe taken intoaccount in constructing a universal calibration graph. The hypothesis concerningthe effect of concentration on the elution volume was supported also by other authors [188-1901, who observed that the effect of concentration on the elution volume in a thermodynamically poor solvent (under theta conditions, when the effective dimensions of the macromolecular coils do not vary with concentration) was weaker. However, this subject still remainsin debate taking into account the experimental data obtained by Dawkins [191-1931, Lecoutier [ 1941, and Garcia et al. [195]. When the organic packing material is crosslinked polystyrenegel and themobile phase is compatible with the polystyrene gel and with the polymer solute, the first condition being more important, solutes do not display preferential affinity or preferential adsorption for themobile or stationary phase. Hence,partition and adsorption mechanisms do not influence the solute size separation [191]. However, when the solute polymers are eluted in poor or thetasolvents for solute and gel (i.e., cyclohexane at with polystyrenesolute and polystyrene gel) solute-gel interactions become important and secondary mechanisms appear with the elution volumebeingdisplaced to highvalueswithrespect to universal calibration. When there is incompatibility between the solute polymer and cross-linked polystyrene gel, elution volumes are shifted toward smaller retention volumes [ 1941. The GPC behavior of synthetic polymers in good and theta solvents has been compared using polar inorganic packings (porous silica) [196, 1971. For these systems observed deviations with respect to the universal calibration are practically independent of the thermodynamic quality or compatibility of the eluent for thepolymeric solute or gel, respectively. The deviations appear when simultaneouslythe interactions between the solvent and gel and between solvent and polymer solute, are markedly modified by using a mixture of two solvents as eluent. Due to the preferential sorption (as a consequence of specificinteractions) of the gel by one of the components of the mixed eluent, a difference in the thermodynamic quality of the mobile and quasistationary phases appears and consequently, additional partition of the solute may occur [197]. Using the latter observations, it was suggested that the thermodynamic quality of the solvent should be estimated from concentration effects [99]. It was also observed that the mutual arrangement of the individual columns affected the concentration dependence of the elution volume [ 1981, and that, with increasing flow of the solvent, the concentration dependence of the elution volume decreased [ 199,2001. An increase in the width of the elution curve with increasingconcentration and volume of the injected polymer solution was observed by several authors [201-2031. Hazell et al. [204] assumed (but did not prove) an increase in concentration
292
Chapter 4
effects with decreasing efficiency of the column, Hellsing investigated the effect of concentration of the polymer present in the mobile phase on the elution volume of natural macromolecules. Bartick and Johnson outlined the possibility of using differential GPC in the study of concentration effects, while Bakos et al. utilized the same method in the study of incompatibility of various polymers and concentration effects under such conditions. Concentration effectswere interpreted by Belenkii and Vilenchik as a consequence of the osmotic pressure at the boundary of the mobile and stationary phase, leading to shrinkage of the gel in the eluting zoneand/or redistribution of macromolecules of various sizes in the polydisperse sample. Cantow et al. observed an exceptionally stronger effect of concentration with samples having a broad distribution compared to those with a narrow distribution. In a seriesof papers, Janca showed that the change in elution volume following a change in the concentration of injected solution in GPC is due to many contributing processes, i.e., the change in the effective size of permeating molecules, viscosity phenomena and secondary exclusion. The first two contributions lead to an increase in elution volumes, while the last, secondary exclusion, causes reduction in elution volumes with increasingconcentration. Song and coworkers presented a theory of concentration effects for polydisperse polymerson hydrodynamic volumereduction and viscosity phenomena. This model predicted the effects of concentration on elution volume, axialspreading, and peak skewing. Theseauthors also reported on a procedure for determining the second virial coefficient of polymersfrom concentration effects Moureyetal. studied the solution properties ofpoly [bis(trifluoroethoxy)phosphazene]and found thatconcentration-inducedchain compression was more severe in a good solvent as compared to a poor solvent. For eluents representing theta solvents for the given polymers, the concentration effect practically disappears; therefore the useof theta eluents is advantageous from this point It has been found that the concentration effects increase with both increasing relative molecular weight and decreasing polymolecularityof the polymer injected. They depend substantially also on the thermodynamic quality of the eluent Since the concentration effect complicates interpretation of GPC data,investigators usually try to eliminate or atleast minimize its influence. Berek et al. found that the magnitude of the concentration effect for polystyrene in some pure and mixed eluents on Si0,-based column material correlates with the product A,M, where is the osmotic second virial coefficient. This correlation was also supported by a theoretical analysis basedon the dependence ofconcentration induced shrinkage of polymer coils on the thermodynamic quality of the solvent
Gel
293
[218]. These authors proposed a qualitative determination of from the concentration effect in GPC, as an alternative to the traditionalmethods of measurement by means of light scattering and osmometry. Ousalem and Busnel [223] discussedconcentration effects for several polymer typesand Hu andcoworkers [224-2261 published a series ofpapers on the concentration effects for polydisperse polymers and applied their theory to universal calibration [224], to radius of gyration calculations [225] and topolyisobutylene rubber characterization [226]. Cheng and Yan [227] studied the effect of polystyrene concentration on elution volume and were able to determine the critical concentration for coil shrinking. Their observations were in agreement with mean-field theory regarding the variation of polymer chain dimensions insolution. Czok and Guiochon [228] reported that viscous fingering is more pronounced with large-diameter columns that with microbore columns. Methods proposed to reduce this effect included increasingthe viscosity of the mobile phase to match that of the injected sample and following the injected sample witha large plug of eluent havinga viscosity slightly higher than thesample. Ye et al. [229] studiedthe effect of polymer concentration in vacancy GPC, a seldom used technique, in which the polymer solution is employed as the mobile phase withpure solvent injectedas the sample.
C. Solvent Effects Unlike other liquid chromatographic methods, the mobile phase in GPC usually is not varied to control resolution. Rather, the mobilephaseis limited to the solvents that can dissolve the sample macromolecule. If permitted, a solvent with lowviscosity at the temperature of separation is preferred to ensure high column plate count (due to improved mass transfer). To maintain high resolution, mobile phases that have boiling points only about 25-5OoC higher than the column temperature should be used. Of course, in the case of difficulty soluble samples, the solvent must be selected primarily to provide sufficient solubility, and viscosity considerations are then secondary. A particular mobile phase has also to be selected on the basis of its compatibility with the solute detector. Thus if a differential refractometer is to be used,the refractive index of the mobile phase should beas different as possible from that of the sample. Or the mobile phase must havea much lower absorption than thesolute at the wavelength of detection with a UV or IR photometric detector. An occasional problem in GPC is molecular association of the sample. For example, the behaviorofphenols and their derivatives during
Chapter 4
294
separation by GPC has been studied in order to explain some features of the mechanism of phenol-formaldehyderesin synthesis [230].The oligomer formed through phenol polycondensation with formic aldehyde, presents various structural forms. Calculations revealed that 13,203 linear isomeric structures are possible for a species made up of 10 phenolic units bound together in ortho or para positions by methylenic bridges [231]. On the other hand, resoles have molecular weight distrbution ranging between 18 dalton (themolecular weight of water) and dalton [232]. Very little is known about the conformation and existence molecular associations formed by phenol and its derivatives withtetrahydrofuran (THF). Hydroxymethylated derivatives of phenols dissolved in THF differ from mono- or polyphenols in that they also may form intramolecular hydrogen bonds in polar solvents. IR spectra of the solutions of these compounds in THF have shown that the peak characteristic the bond between the phenolic or alcoholic group and THF is found at 3280 and 3430 cm", respectively. Within the same field (3240 cm") there appears the bond characteristic of the intramolecular bond between the phenolic "OH group and the ortho-hydroxymethylene group. One has an adsorption in the same domain cm"). Consequently, the IR spectra of the omethylolphenol solution in THF cannot determine the nature the solutesolvent interactions. One should choose betweenthe two possiblestructures presented in Fig. 3. the intermolecular hydrogen bonds require the phenolic hydrogen, which has an acid character, conformation 1 (Fig. 3) has a reduced probability. Such a hypothesis is also supported by the behavior of this species during separation by GPC [230]. Further anomalies have been observed in the elution of styrene oligomers [233]. In a polar medium (e.g., dimethylformamide), the mixture of l-methyl-3-phenylindane and 1,3-diphenyl-l-butene (two dimers of styrene) behave like a monocomponent compound which, depending on the composition of the mixture, leave GPC columns at different values of VEL.
1
2
Figure 3 Two possible structures of hydrogen bonds in o-hydroxymethylated phenol-THF system.
hromatography Gel Permeation
295
All attempts to explain this behavior have, to date, been unsuccessful. However, controlled sample association can be advantageous for certain separations by GPC. The effect of the solvent on thevarious GPC packings must be considered. For example, the crosslinked polystyrenegels for GPC can tolerate a moderate range of organic solvents, but acetone, alcohols, and otherhighly polar solvents cannot be used. Aqueous systems outside the pH range of about 2-8 degrade siliceous packings. Strong bases, such as NaOH and tetramethylammonium hydroxide, should be avoided but organic amines (e.g., triethylamine) are well tolerated [234]. Salts ingeneral appear to hasten the degradation of silica packings,particuarly at temperatures above ambient, the effect of direct function of pH and ionic strength. The solvent that causes collapseof organic gels for GPC must be avoided. However, in GPC with certain very polar solvents such as DMF, a salt must often be added to the solvent to reduce solute adsorptive effects and maintain a constant ionic strength. However, large changes in salt concentration can cause an organic gel to collapse. Many commonly used solvents for GPC are listed in Table 1 together with most ofthe properties of interest [235].
D. Instrumental Anomalies Some instrumentalists have shown that apparent flow rate dependent elution volumes can result from instrumental anomalies, i.e., the performance of the instrument depending upon the flow rate of solvent through it. Two such anomalies were documented by Yau, Suchan, and Malone [236] on instruments that use a siphon for the purpose of monitoring the flow and elution volume. The first anomaly was due to the fact that solvent would continue to flow into the siphon as it was discharging. This anomaly results in apparent elution volumes appearing lower than they actually are and in apparent elution volumes decreasing with increasing flow rate. The second anomaly was due to the fact thatsolvent couldevaporate before the siphon discharged. At slow flow rates a significant portion of the solvent in the siphon could evaporate before the siphon discharged.This would also result in apparent elution volumes that were lowerthan the true elution volumes. However, since the evaporation effect decreases as the flow rate increases, the apparent elution volume would increase with increasing flow rate. When both of these anomalies are operative, the apparent elution volume increases with low flow rates and then decreases with high flow rates. A plot of apparent elution volume versus flow rate would show a maximum for a given molecular species. Yau, Suchan, and Malone demonstrated that these two anomalies were the major contribution their to observed flow rate dependent elution volumes.Withthese instrumental
Chapter4
296
Table
Properties of Solvents Commonly used in Gel Permeation Chromatography
Solvents Tetrahydrofuran 1,2,4-trichlorobenzene o-Dichlorobenzene Toluene N,N'-Dimethylformamide Methylene chloride Ethylene dichloride N-Methylpyrrolidone m-Cresol Benzene Dimethylsulfoxide Perchloroethylene oChloropheno1 Carbon tetrachloride Water Trifluoroethanol Chloroform Hexafluoro-isopropanol
Melting point ("C)
Boiling point ("C)
-65
66 213 180 110.6 153 40.1 84 202 202.8 80.1 189 121 175 76.8 100.0 73.6 61.7 58.2
17 - 19 -95 -61 -97 - 36 - 24 12 5.5 18 - 19 7 -23 0
-
-64 -34
uv cutoff (nm)
220 307 204 285 275 245 230 262 302 280 260 290
-
265
-
190 245
190
Refractive index at
1.4072 1.5717 1.5515 1.4969 1.4294 1.4237 1.4443 1.4700 1 S440 1 so11 1.4770 1.505 1.5473 1.4630 1.33 1.2910 1 .4457 1.2752
anomalies accounted for, Little et al. found no flow rate dependence of elution volumes on an instrument that was similar to that used by Yau, Suchan, and Malone Retentionof the solutebymechanisms other than sizeexclusion greatly complicatesthe process of obtaining sample molecular weight information from GPC data. Adsorption or "matrix" effects involvinga form of partition or adsorption can be superimposedon size exclusion, resulting in excessive retention that the desired relationship between retention volume and molecular size isnot obtained. Adsorption or matrix effects can often be minimized by utilizing the most polar mobile phase permitted by sample solubility.For example, water is an effective mobile phase with unmodified siliceous particles for some separations. At pH >4, the acidic Si-OH groups on silica are ionized and can function as ion-exchange sites. Aqueous phases containing buffers or salts can be used effectively to eliminate undesired ion-exchange interaction of certain solutes (e.g., proteins) with unmodified siliceous surfaces. Where permittedby the sampleproperties,working at pH <4 often will also
hromatography Gel Permeation
297
eliminate unwanted ion-exchange effects. In GPC highly polar solvents such as hexafluoroisopropanol and dimethylsulfoxide have proven to be useful in eliminating the adsorption of polar polymers to surfaces of unmodified silica particles. Unwanted interactions of solutes with organic gels are also widely recognized. For example, Sephadexand Bio-Gel P contain asmall number of carboxylic acid groups which can ionize and exhibit cationic exchange properties in eluents of low ionic strength at pH >4. In some cases ionic interaction between the solute and the carboxylic groups in the matrix is strong that suppression of the ionization of the carboxylic groups is necessary. Other mechanisms of interactions between organic gels and aromatic and heterocyclic solvents suggest involvement of the ?r-electron systemof the solute and an electron-deficient or electronegative portion of the gel matrix. Hydrogen bonding between substitutents on aromatic solutes, or the heteroatom of heterocycles solutes, and certain functionalities on the organic gels is also possible. Non-size exclusion effects in GPC and mobile phase optimizationwere reported for cellulose nitrate [238], lignin [239,240], polyamic acids [241,242], poly(acrylic acid)[243],poly(amideimide) [ M ] poly(viny1 , pyrrolidone) 12451, asphalts [246], polycyclic aromatics [247], and alkyd resins [248]. The theoretical interpretation of the behavior of small molecules or oligomers during separation through GPC are based, partially or totally, on the theories proposed for the GPC of high polymers. Disagreements, observed mainly in the attempt to establish a suitable parameter for GPC calibration, have been caused, in our opinion, by the fact that structural characteristics and solvent-solute interactions dominate over the separation mechanism of exclusion. This observation is supported by early experimental data thatevidenced the very special behaviorof aromatic hydrocarbons [249-2571, as well as the influence of functional end groups on the GPC separation of oligomers[258-2651.
VII. ASPECTS OF GPC ANALYSIS OF COPOLYMERS Because the molecular size of dissolved molecules varies with composition and structurein the case of block and random copolymers, there has beena problem in establishing accurate molecular weight calibration for polymer or oligomer systems of varyingcomposition and for systems where composition is a function of molecular weight. In practice the use of GPC with selective detectors [266-2711 and the application of interactive liquid chromatographic modes are the procedures applied for measuring compositional heterogeneity in these types of polymers [272-2741.
298
Chapter 4
The fundamental existenceofso-calledcriticalconditionsiswellknown in polymer chemistry and in chromatography [275-2821. In these conditions the entropy losses of a macromolecule within a pore and the enthalpic effects due to adsorption of the chain units on thepore walls are exactly compensated. Underthe critical conditions, when passing from the solvent volumeinto thepores, the free energy changefor a macromolecule is found to be zero (the distribution coefficient K = 1). The first experimental works in connection with this subject were published by Tennikov and coworkers [283,284] and subsequently the results were confirmed for different polymersand various solvents [285,286]and a theoretical foundation was elucidated [287-3001. The Russian scientists use the expression that macromolecules become “invisible,” in order to emphasize that, under critical conditions, the retention volumes of homopolymer macromolecules of any molecular weight become equal to the retention volume of solvent molecules, in sucha way as to make them indistinguishible from each other and from the solvent. The idea of chromatographic “invisibility” has been used [288] with the aim of building up a theory of a two-block copolymer separation according to the lengths of one “visible” block only, provided that the copolymer was exposed underthe conditions criticalfor theother “invisible” block. The method of “invisible” is, in a way, analogous to the well-known procedure [289] of copolymer analysisby means of light scattering, where a solvent is chosen that has a refractive index identical withthat of one of the copolymer components. This results in the optical invisibility of this component and makes the measurement of the radius of gyration of the visible component possible. Critical conditions can be created experimentally by means of particular choices of mixed eluenttemperature or pH (when aqueous eluents were used) variations, etc. The results of this method of “invisible” providean efficient separation of macrocycles and linear polymers and theseparation of macromolecules accordingto the number of functional groups. The method of “invisibles” also makes it possibleto separate two-block copolymers accordingto the size of the “visible” block only, and to separate grafted polymers according to the backbone length [291-2941. The method of “invisible” in polymer chromatography is exactly rigorous for a number of polymer systems that contain a single continuous “visible” chain fragment. In particular, monofunctional macromolecules, two-block copolymers, three-block copolymers with the central block being investigated, partially cyclic macromolecules, and graft copolymers with “invisible” side-chains belongto such systems.The most convenient realiza-
hromatography Gel Permeation
299
tion of the method of “invisibles” in such systems would beobtained using wide-pore adsorbent. For other systems, e.g., copolymers with several “visible” fragments jointed together with “invisible” inserts, the method of “invisibles” becomes rigorous whenusing narrow-pore adsorbent only, the pore sizesbeing smaller than those of all the chain elements under critical conditions. For the realization of the method of “invisibles” in such systems, itis important to have narrow-pore adsorbents, with a uniform pore surface, and also to be able to select conditions that are both critical for one of the copolymer components and at the same time do not cause strong adsorption of the other “visible” component. This can be achieved by choosing a suitable eluent, variations of temperature and adsorbent surface modification. The theoretically predicted efficiency of the method of “invisible”for functionally active macromolecules has been demonstrated experimentally in detail for a large number of polymer systems,and areview waspublished by Entelis et al. [290]. Some other predictions of the theory, in particular the possibility of the application of the “invisibility”method to the analysis of both block and graftpolymers and to theseparation of linear and cyclic macromolecules, havenot received experimentalcorroboration to date. Molecular weight-sensitive and information-rich LC detectors have beenextremelyvaluable for characterizing complexpolymers. GarciaRubio [301,302]used simulation studies to investigate joint molecular weight-chemical composition distribution and secondary fractionation effects of linear copolymers. Compositional heterogeneity of methyl methacrylate-styrene copolymers was determined by using 3-phenylazobenzoyl peroxide as a initiator and labeling agent[303J . The use of a photoiodide array detector with GPC was described by Del Rios [304]. UV Spectrophotometric detection is the most widely used approach for determining chemical heterogeneity of complex polymers. UV detection was used to determine compositional heterogeneity of wood components [ poly(ethy1ene terephthalate)-poly(tetramethy1ene ether) multiblock copolymers [3061, and styrene-butadiene-styreneblock copolymers [3071. Using GPC coupled to UV and IR detectors Verenich et al. [308] determined the compositional heterogeneity of oliogmeric epoxy propiolates. On-line IR was used to determine functional group distribution of poly(dimethylsi1oxane)s [3091. Kilz [310,311] useda four detector system consistingof a multi-angle laser-light-scattering photometer, refractometer, UV detector, and an online viscometer for the characterization of block and statistical copolymers as well as for star- andcomb-shaped polymers. Grubisic-Gallot etal. [312]
300
Chapter 4
also used a fourdetector system for thecomplete characterization of several different types of block copolymers.In their system, a low-angle laser-lightscattering photometer was employed. Trothnigg [313,314] used an on-line density detector in series with a refractometer to characterize the composition ofpoly(ethy1eneglycol)poly(propy1ene glycol) blendsand copolymers of ethylene oxideand tetrahydrofuran. Mork and Priddy [315]determined the extentofphenolic end-capping in bisphenol A polycarbonates using GPC-UVdetection. Warner et al. [316] used GPC-UV detectionto determine the amount and location of functional groups in styrenic polymers. Pasch and coworkers [317] relied on UV detection for the analysis of polymers containing UV stabilizer units. UV-GPC was used in the characterization of polystyrene-poly(2,4dimethyl-l,Cphenylene ether) blends [3 181, and polyester-polycarbonate blends [3191. Podzinek et al. [320] used GPC-UVfor determining the composition of polyesters. The compositional heterogeneity of nonstoichiometric polyelectrolyte complexes between polymethacrylate and poly(N-ethyl-4-vinylpyridinium bromide) was investigated by Efremov et al. [321] using GPCUV. Styrene propylene oxide block copolymers [322]and linear and cyclic siloxane copolymers [323]also are characterized using this technique. An on-line interface for GPC/FT-IR to remove high-boiling mobile phases for subsequent FT-IR detection was described by Dekmezian and Morioka [324]. GPC/NMR was employed to characterize isotactic poly(methyl methacrylate) [325] and block and random copolymers of methyl and butyl methacrylates [326]. The use of multiple modes of liquid chromatography to determine the chemical composition of distribution ofcomplexpolymershasreceived considerable attention during the last ten years. Investigators are finding it convenient to first separate by molecular size, followed by adsorption chromatography. This approach has been used by Mori [327-3301, Glockner[331-3351, and others [336,337] for the characterization of various copolymers. Also, Jiang et al. [338] first fractionated copolymers blends by precipitation followed byGPC. Techniques involving the coupling of GPC columns to a reversedphase system have been reported for theseparation of proteins [339], glycoproteins [340], and additives in cellulose acetate [341]. A GPC/capillary electrophoresis apparatus has beenreported for thecharacterization of proteins [3421, and seeRefs.343-346 for other studies dealing with multiHPLC approaches for protein separation. An interesting multidimensional technique was reported by Cortes et al. [347], in which a GPC microcolumn system was coupledto a pyrolisis GC apparatus for the characterization of acrylonitrile-styrene copolymer.
Gel
301
Fujimoto andcoworkers [3481 described a technique utilizing microcolumn GPC followed by thin-layerchromatography (TLC). Detection was accomplished on the TLC plates withFT-IR. Orthogonal chromatography has also been used for the separation of complex polymers. With this approach, the sample is first separated by GPC in a given mobile phase. Through the use of a switching valve, the separated components are then eluted through a second column utilizinga poor solvent asthe mobile phasethat will either change the conformationof the polymer or encourage interaction with the packing [349-3511. Finally, Palladino andCohen [352] useda photoiodide array detector with GPC to measure secondorder derivative spectra of polypeptides. By comparison of these spectra to those of known amino acids and heterodipeptides, identification of the composition of unknown peptides was possible.
VIII. SELECTED APPLICATIONS Although lacking a suitable theoretical base for a precise method of estimating its results,the GPC remains one of the most frequently used methods in the characterization of macromolecules [353-3631. This section coversselected applications of GPC in the field of naturaland synthetic oligomers and polymers. In polymer dope dyeing, the dyestuff is introduced into thepolymerization system during synthesis. For this purpose, either reactive or inert dyes may be used [364-3661. In the first case, the dyestuff becomespart of the main chain by combination with suitable functional groups. In the second case, the dyestuff isdissolvedin a polymermoltenmass and a physical blend of macromolecular product and dyestuff is obtained. This process is applied in industry for poly(ethy1ene terephthalate)-PET-dope dyeing. The difference between dope-dyed polyesterand colorless polyester obtained under the same experimental conditions is shown by a lower intrinsic viscosity and higher amount of “COOH end groups and diethylene glycol (DEG) units. Efforst have been made to avoid these disadvantages by shortening the contact time between polymer and dyestuff during polycondensation. The results were not successful and polyester fiber and yarn producers now accept these specialfeatures of dope dyeing because of the economic characteristics of the dyed polymer obtained. The gel chromatograms of dope-dyed PET show the systematic influenceof dyestuff on the value and distribution of molecular weight in dope-dyed PET. In an experiment performed byus [367] polymer was obtained by batch reaction in a laboratoryplant. The polycondensation was completed in 270 min. To be able to follow the oligomer transformation during polycondensation, the process was interrupted after 90, 120, and 210 min. The
302
Chapter 4
samples obtained in this way will be called“interrupted samples.” Thus, we obtained 12 interrupted samples and 3 end products (items 1and 2 in Table 2 for colorless polymer, items6 to 10 for blue polymer, and items 10 to 15 for red-colored polymer). The dyestuff (1070 by weight for dimethylterephthalate, DMT) was introduced at the beginning of the polycondensation stage. The chemical and molecular characteristics of the resulting products are given in Table 2. The molecular weight distribution in the synthetized sampleswas determined by GPC. Theelution was carried out at 100°C by using a mixture of nitrobenzene-tetrachloroethane(NB-TCE) (5:95,v/v). The samples were dissolved in pheno1:TCE (3:2). Before use, TCE was neutralized and stabilized as follows: freshly distilled TCE was treated twice with 5% aqueous Table 2 SampleCharacteristics data
GPC
No.
-
dyestuff
M,’
data Analytical COOH [SI g-106) (dl/g)
Dmc (Vo)
1 77.0 0.075 3.45 1,010 0.205 2 22.0 1.29 4,270 0.293 1.96 3 CSd 35.0 6,750 0.611 1.72 4 49.6 16,500 0.740 1.09 5 57.0 21,000 0.080 6 1,400 200.0 6.40 2,800 0.120 1.50 7 0.105 168.0 1,950 0.180 8 ERLS‘ 98.0 3,700 2.55 96.09,6000.225 4,2700.210 2.50 9 . 4,550 10 78.0 38,500 16,500 0.6102.60 17,000 0.620 11 0.082 5.45 1,150 137.9 12 0.085 1.40 1,550 120.0 13 ESGFP‘ 0.255 3.00 47.0 5,200 0.365 3.01 14 58.2 11,OOO 58.7 0.545 3.20 15 17,200
(dl/g)
M,
-
-
0.080 0.140 0.240 0.690 0.760 0.110
1,480 4,000 6,800 13,400 24,700 2,300
2,200 7,500 10,300 20,100 58,300 3,100
0.140
3,700
4,600
0.75 0.71
21,500 19,500
69,000 55,000
[SI
Industrial samples
I I1
22,000 19,800
28.0 68.6
0.760 0.725
0.55 1.66
‘Determined by titration of end groups; bdetermined by potentiometric titration; ‘determined by gas chromatography; dcolorless samples;Tstofil Blue RLS (produced by Sandoz); ‘Estofil Red SGFP (produced bySandoz). Source: Ref. 367.
Gel
303
KzC03solution (10 m1 solution KzC03per loo0 mL TCE) with stirring for 30 min in each treatment. After separation of the aqueous phase, 1 mL of propylene oxide was added per 1,OOO mL and the TCE was then mixed in the required ratio with NB. The mixture was kept on silica gel until use (10 g silica per 1O ,OO mL), in brown, closed bottles. These experimental conditions were chosen for GPC to avoid the high viscosity the phenol-TCE mixture and because PET solutions in the TCE-NI3 mixture ( 9 5 5 v/v) are not stable. Table 2 shows that the colored samples are characterized by a higher content of “COOH end groups than the colorless samples. This finding suggests the occurrence ofa degradation reaction during the preparationof dope-dyed PET. Since the coloring matters used have a l-aminoanthraquinone structure in which hydrogen atoms of amine groups are partly substituted by different radicals, the higher content of “COOH end groups in colored PET may be explained easily.The basic character of the aromaticamines is decreased byp-?r conjugation which involves the unpaired electrons of the nitrogen atom and the n-electrons of the benzene ring. This process gives an extra positive charge at the nitrogen atom, that induces polarization of the ester link. See the following reaction: OkH2 --C
6+
, CH“O-C“C6H~” -H
a+
6-
4 +
0
+ CHz=CH-O-C-C$&-
“C \
OH
a
NH-R
1 NH-R
A
A
I
l
(51)
in which A = antraquinone rest and R = 1,3,5-trimethylphenyl or - C O - C ~ s . The GPC data confirm the systematic influence of the dyestuff on themolecular weight distribution of dope-dyedPET (Fig. 4) [367]. The analysis of product characteristics shows that in the firststage of the polycondensation process (after 90 min) the molecular weight distribution (MWD) of the dyed polymer shifted to the range of higher molecular weights. The same results wereobtained from the values of M,, and M, for samples 1 and 6 (Table In Table 3, the frequency of the species per range of molecular weight for samples 1 to 10 is given. From these data, it can be seen that sample 1 contains a higher amount of species with M,, < lo3than sample 6. Concerning the species with lo3 < M,, < lo4,sample 6 has a higher percentage. Asa result of this uneven distribution of species in the molecular weight range in samples 1 and 6, the dyed polymer has a higher M, and M , than thecolorless polymer. In the subsequent stages of polycondensation, the presence of dye-
Chapter 4
14
16
18
20 22 U ve,lcounts
-
Figure 4 Gel chromatogram of colorless samples (-) and dyed ones ( (A) After 90 min; (B) after 120 min;(C) after 180 min;(D)after 210 min; (E)after 270 min; (F) industrial sample. (From Ref. 367.) e).
Table Species Distribution (To) per Range of Molecular Weightin the Analyzed Samples
G
G,,of colorless samples
of colored samples
"
No. < l o 3< l o 4> l o 4 20.411 6.49 2 3 4 5
-
-
Source: Ref.
75.68 3.91 86.37 7.14 58.97 41.03 21.01 78.99 6.50 93.50
MJM,, 1.48 1.87 1.51 1.50 2.36
"
No. 6.27 6 7 8 0.71 9 10
-
> l o 4 MJM,,
93.73 98.15 95.73 77.44 19.68
-
1.34
1.85 4.23 21.85 80.32
1.24 2.24 2.33
1.25
Gel
305
stuff is accompanied by a systematic shift of the distribution curves of colored PET to the range characteristic of the low molecular weight species. This is shown bythe location of the distribution curves in Fig.4, and by the species distribution per range of molecular weights (TableThe change in the direction of the value of the molecular weight and MWD of colored PET caused by the dyestuff is the result of the mechanism that dominates the interaction between polymerand dyestuff. In the first stage of polycondensation (after 90 min), the main influence of the dyestuff is to decrease the melt viscosity (in industrial autoclaves, this influence is shown by a decrease in the power required to drive the stirrer). The decrease in melt viscosity is not accompanied by a reduction of polymer molecular weight, but is more a consequence of PET melt plasticization caused by the presence of the dyestuff in the system. This conclusion is shown by the values of the molecular weight of samples 1, 6 , and 11 and by the gel chromatograms of samples and 6 . As a result of the easier removal of ethylene glycol from the system due to the decrease in melt viscosity, the molecular weight of the colored polymer is higher than that of the colorless one 90 min after thebeginning of the polycondensation. In the later stages of polycondensation, the presence ofthe dyestuff is accompanied especially by a supplementary degradation effect made evident in the dyed samples by the diminished value of the molecular weight, the higher amount of “COOH end groups and diethylene glycol, and the profiles of the gel chromatograms of samples 7 and (Tables and and Fig. 4). The presence ofthe dyestuff in PET results inthe appearance of some specific peaks in the gel chromatograms of low molecular weight species (VEL= counts in curve A, VEL= counts and 21.5 counts in curve B, Fig. 4). These peaks correspond to M , values of and 1,600 dalton, respectively. Gel chromatograms of the colored samples have, as specific characteristics, the appearance at V,, = to 28 counts for some specific peaks (which are not shown in Fig. 4) due to thedyestuff. The eluent separated in the fraction collector at VEL= to counts was colorless, while the eluent separated at VEL= to 28 counts was blue. The possibility of separating the dyestuff from thepolymer by GPC supportsthe conclusion that there are no covalent bonds between polymerand dyestuff. Introduction of some “colored structures’’ in the PET backbone by using the corresponding dyestuff allowsthe synthesis of some colored products without altering the characteristicsof the white polymer [368-3721. The insertion of reactive dyestuff N,N-bis(ethoxycarbonylphenyl)pyromellitic diimide with the chemical structure givenin formula is proved by IR spectroscopyand GPC data.
Chapter 4
306
0
0
II
II
C
C /
\
HSC,OOC"C6H4"N
/
\
\
/
N"C6H4"COOC2H,
C6H2
\
/
C
C
0
0
II
In a recent paper, Libert and Markhal reported that, during the introduction of the functional dye inthe main chain of polymers, no change in the structure of the chromophore takes place (its IR spectrum did not change). Comparing the colored polymers with the corresponding monomers, it was observed that the spectra of polymers were slightly broader than that the monomer. This phenomenon was probably caused by the interaction of the chromophores stacked along the backbone. The behavior of dope-dyed PET and self-colored PET (with reactive dyestuff) in the separation by GPC confirm this view. The gel chromatogram of dope-dyed PET shows both a separate, distinct distribution curve for PET (theeluent collected between and 22 counts was colorless) and the characteristic peaks of Estofil Blue R L P . In this case, the separated eluent between and counts was blue. Gel chromatograms of self-colored PET did not reveal the characteristic peak of N,N-bis(ethoxy-carbonylpheny1)-pyromellitic diimide, whilethe eluent collected between and 19 counts was yellow (Fig. Mention mustalso be made of more recentstudies performed in order to determine the optimal conditions of separation by GPC instrumentation and applying GPC in the determination of the molecular weight distribution within various oligomeric and polymeric mixtures obtained through polymerization or polycondensation. Table contains references to selected examples of GPC separations that have been used successfully for the characterization of oligomers, polymers, or for a variety of analyses biochemical interest.
IX. RECYCLE CPC AND HIGH-PERFORMANCE GPC The matters discussed up to now have addressed the limitations of GPC. These limitations have tendedto improve the performances of this method, mainlyin the separation oflowmolecularweightspecies.Two major achievements reported to date, the recycle GPC and high-performance GPC (HPGPC)techniques should be mentioned. Recycle GPC is a special technique of column programming for im-
307
Gel Permeation Chromatography EPDI
ESTOPIL BLUE RLS
Self oolored Colorlesseluent
0
PIST
Blue ooloredeluent
4 (/,
dyed
4 *.
2
*
Indwtrfal aolorleee
16 16
20
22
24
26 28 30 vel/cormte
Figure 5 Gel chromatogramsof EPDI, N,N'- bis(ethoxycarbony1-pyromelliticdiimide) samples.
proving resolution by passing the sample through the column, or set of columns, repeatedly. Yet, recycle GPC represents an efficient way exceeding the intrinsic limits of GPC and also of solving new details of the composition natural (suchascrude oil) or syntheticlowmolecular weight mixtures. In practice, recycle GPC was introduced by Porath and Bennich [589] and developed by Biesenberger et al. Nakamura et al. Uglea and Cincu [594], Bombaugh et al. [595] and by Trolltizsch [5961. Recyclingwasoriginallysuggested for use in gas chromatography [597] where it was never used in practice because of technical difficulties and lack of incentive. In this technique, the column eluent is repumped through the column instead of mobile phasetaken from the reservoir, and the sample is thus analyzed several timeson the same column, that the resolution between its components can be increased. Since its introduction, the advantages of recycling have been widely
308
Chapter 4
Table 4 GPC Application to Natural and Synthetic Oligomers and Polymers
Polymer A . Synthetic Polymers
Elastomers Polyacrylamide Polyamides Polyanilines Polyketones Polybutadiene Polyisocyanates Polyacrylates Polyolefins Polysiloxanes Polyesters Polyurethanes Poly(viny1 acetate)s Poly(viny1 alcohol) Resins Alkyd EPOXY Phenolic Oligoethers Oligosulfones Polycarbonate Oligoisobutylene Oligoquinazolines Polystyrene Cyclics Oligo(oxyethy1ene) Copolymers
[401,402] t 403I 404-41 l] 14121 [413,414] [4151 t416-4211 [422-445] [446-4481 [449-4591 [460-482] [483-4871 [4881 [489,490]
W
1
t492-4981 t499-5111 [512-5151 [516-5191 15201 [5211 t 5221 [523-5291 [5301 15311 [532-5381
B. Starch, Cellulosics, Lignin, and Other Polysaccharides Starch Cellulosics Other polysaccharides
[539-5421 [543-5491 [550-559]
C. Asphalt, Bitumens, and RelatedProducts
Bitumens Asphalts Maltenes Tars
[560,561] [562-5641
5651 [566,567]
-
Gel Permeation Chromatography
Table 4 Continued
Target D. GPC Applications
Biochemical Interest
Industrial proteins Purified synthetic peptides Amyloid &A4 peptides Cyanogen bromide fragments of Semipurified protein digest collagen Nonglycosylated mucin peptides Mucin core protein proteolytic digest Ascites fluid Monoclonal antibodies Recombinant HIV gp41 protein Urea extract of inclusion bodies Envelope proteins of HSVvirus Soluble extract of virions Water-soluble tissue extract Fetal lens crystallins In vitro environment Aspartate transcarbamylase Recombinant farnesyl diphos- Bacterial extract phate synthase Escherichia coli Shiga-like toxin In vitro environment I1
Retinoic acid binding activities CAMP-dependent protein kinase Wheast flour proteins Caprine whey proteins Amylase-pullanase Proteoglycans Mucins, mucin-derived oligosaccharides
Tissue nuclear extract In vitro environment Detergent extract of wheast Rennet whey Bacillus circulans
Human tissues Animal tissues
used in gel filtration and GPC. In this case, the span of retention is very narrow and long columnsare therefore necessary in order to achieve separations, but it is impossible to use long columns at relatively large mobile phase velocities becausethe gel packings cannot stand large pressuredrops, even if the pressure gradient is moderate. Thus recycling offers a practical solution. Recycling has generallybeenused to achieve the large number of theoretical plates required to obtain a satisfactory resolution of closely eluted components. Today, however, the development of efficient techniques for packing columns with very small particles makes possible the achievement, in a reasonable time, of large plate numbers (several tens of thousands or even several hundred thousand plates) while using relatively moderate pressure drops. Hence, it isquestionablewhetherrecyclingis needed any longer in common practice.
Chapter 4
310
The simplest recycling techniques consist in connecting the detector output with the pump inlet, as shown in Fig. 6. The sample, introduced in the injection port, percolates through the column and the detector and is then recycled via the four port valve through the pump into the column. For recycle operation, thevalve is in the position of the dotted line and for collection in the position of the full line. The scheme illustrated is very simple. The basic principle of this recycling technique is the directpumping. The othermethod was presented by Biesenberger et al. [590-5921and adapted tohigh-performance liquid chromatography by Henry et al. [598]. Fig. 7 shows a schematic diagram ofthis version, termed “alternate pumping”recycling. In this configuration, two nearly identical columns, two detectors or one dual-cell detector and one six-port, two-position valve are needed. In the actual full-line configuration in Fig. 7, the sample flows from the injector to column 1, detector 1 and through thevalve to column 2 and detector Whenall of the sample is in column2, the valveis switched so that column 2 becomes upstream of column 1 and the sample can return to column 1. To minimize the contribution of the injection to band broadening, the injector can be set between the valve and the column, near the last one. Although recycle GPC has received muchattention in the commercial literature, its real utility seems limitedto applications requiring the separation of two compounds with almost identicalelution behavior. Conventional GPC does not provide the required resolution in the low molecular weight region for controlof the molecular weight distribution in the oligomer-polymer systems. Withthe advent of high-efficiency columns (particle diameter, pm), the resolution in this molecular weight range of 200 to 10,000 dalton has been greatly improved, and conventional GPC becomes high-performance GPC (HPGPC). Even if the estimation of the performances of chromatographic columns, especiallythe GPC ones, is not
Injector
Column
Detector
Solvent Supply
Figure 6 Schematicdiagram ratus.
adirectpumping(closedloop)recyclingappa-
311
Gel Permeation Chromatography
3. Detector 2
I
I
f
Detector 1 l'
!l
Drain
Column 1
Column 2
9
Injector
l"
Pump
Solvent Supply
Figure 7 Schematic diagramof an alternate pumping recycling apparatus. standardized yet, it is generally acceptedthat if a set of columns haslo4 to lo4theoretical plates, then conventional GPC becomes HPGPC. Specific applications of HPGPC include quality control of supplier raw materials, guiding resin synthesisand processing in order to improve end-use properties, and correlating oligomer and polymer molecular weight distributions with end-useproperties. Another field of HPGPC utilization is the characterization of coating systems. Although coating systems and lacquers have been known since cave-dwellers decorated the walls of their abodes, it has only been within the last century that any scientific consideration has been given to them. The organic coating systems commonly called paints, varnishes, and lacquers are usually complex blendsof two (or more) phases, a pigment phase and a vehicle phase.It is the vehicle phasethat can be fruitfully investigated by HPGPC. This film-forming phaseis itself a complex mixture composed of resin, plasticizers, solvents,and various additives. In recent years, new techniquessuch as power,high-solid,waterborne/water based, and radiation-curable coatings have been developed to meet the challenges of official regulations in the areas of ecology, energy,
Chapter 4
312
and consumerism. These constraints call for the design of a carefully tailored molecular weight distribution to minimize the presence of volatile components. They also require the use water as the majorsolvent or the use tailor-made low molecular weight polymers, oligomers,and reactive additives which, whenfurther reacted, produce high molecular weight and crosslinked polymers concomitant with minimization of volatile organic compound emissions. Consequently, the quality control of raw materials and determination of the oligomer/polymer ratio as well as the molecular weight distribution of the binder resins are critically important for the attainment of desired performance properties from these new coating technologies. Powder coatings are designed to be 100% solidsand usually contain a lowmolecularweightpolymer and an oligomericcrosslinkedpolymer. Also, a powder coating contains a small amount of anoligomer flowagent to aid flow and leveling during the baking process. However,the molecular weight distribution low molecular weight components should be chosen in such a way that (1) the powder particle will not coalesce upon storage; ( 2 ) the resin system will meltand flow withappropriate leveling characteristics, optimum for appearance properties, prior to the crosslinking reaction within specific time constraints at a given temperature; and the crosslinking reaction must occur at the appropriate time after the resin has melted, consistent with the development both good appearance properties and good mechanicalproperties. Therefore, the molecular weight distribution of polymeric and oligomeric components must be carefully designed and controlled. HPGPC was used for the characterization of incoming raw materials and also to aid a resin chemistin developing an in-house oligomeric component for a powder-coatingsystem [599,600]. For high-solid coatings, HPGPC is very useful for screening various resins for the optimization of coating viscosity (molecular weight distribution) and cured filmproperties. High-solid coatings are those which are usually 62.5% or more nonvolatile on a volume basis. These coatings contain oligomers = 500). The key design parameters in high solid coatings are low viscosity, low volatility, and controlled reactivity. Radiation-curable coatings, via UV radiation, consistofverylow molecular weight multifunctional oligomers diluted with reactive monomers and contain a photosensitizer to promote crosslinking reactions. This type coating is ideally suitedfor flat stock such asfloor tile and interior wood paneling. The molecular weight distribution of the oligomer must be maximized consistent with acceptable rheological properties. HPGPC is useful for guiding resin synthesisand process development. Electron beam coatings consist of anunsaturated oligomer mixed with
(a,,
Gel
313
reactive monomers. The molecular weight of the oligomer is very lowand HPGPC is again useful for guiding the oligomer synthesis and to monitor the process. Water-borne coatingsare prepared in water-miscible organic solvents up to to 80% solid by volume. These coatings usually are in the to 30,000 molecular weight range and contain polesters, alkyds, acrylics, and epoxy resins.HPGPC has been usedto monitor the molecular weight distribution of raw materials and for periodic characterization of the sample from storage tanks or production tanks [604]. The molecular weight distribution of oligomeric mixtures may also be studied by the semimicro GPC technique [602,603]. In this procedure, several polystyrene gels of different pore sizes were packed into a 500 X 2.1 mm i.d. column. enable semimicroGPC tobe carriedout with a system consisting of a triple piston pump, a microloop injector and a fluorocell with a volume of 1.0 m1 were constructed. This improved apparatus was developed because the dead volume ofthe injector and the cell in the conventional equipment determine a significant loss in terms of column efficiency. The effect of sample amount, injection volume, and mobile flow rate on column efficiencyand retention volume were optimized. The sample amount ( < 5 0 0 pm), injection volume (< 15 pL), and flow rate range (30 to pL/min) are the optimal operational variables for semimicro GPC. Oligostyrenes, epoxy resins, phenol-formaldehyde resins, and phthalates were analyzed by the semimicro-GPC system under given conditions [602, 6031. This method showed good accuracyand reproducibility and was preferred to liquid chromatography techniques.
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Index
Acrylamide, 270 Adsorbent, 8 1 Adsorption, 45,81 Aerosil, 88,94 Agarose, 19 1 [4-(Allyloxy)benzoyl]4methoxyphenyl, 102 Alumina, 84, 109 Aluspher Al, 110 Aluspher-Select B, 110 Amyloglucosidase, 187 Analyzer amino acid, 141 nucleic acid, 141 urine, 141 Area, specific surface, 85
Azeotropy, 137
BAMB-1 theory, 46 Band broadening, 281 by extracolumn, 156 Bandwidth, 60 Benzoquinone, 23 Bio-Gel P, 270 Broadening effect, 123 definition, 128 theory, 127 1,4-Butanediol, 39
p-t-Butoxy-carbonyloxystyrene,113, 114 Calibration direct, 275 integral, 280 linear, 280 universal, 275 Capacity factor, 51, 129 341
342
Carborane, 27 Chromatographic optimization,138 total chromatographic optimization (TOCO), 139 Chromatographic response, 138 hierarchical, 138 Coupling theory, 124 Detector absorption-polarimetric, 179 ampermetric, 184 chemiluminiscense, 177 circular dichroism, 179 diode array, 175 diode-laser based, 178 electrochemical, 163, 182 electrochemicalarray, 185 electrokinetic, 183 element specific, 179 flame ionization, 142 flame photometric, 179 fluorescence, 142, 176 mass spectrometric, 181 refractive index, 176 stereoselective, 188 UV-VIS, 173 voltametric, 182 Dextran, 270
3,3-Diamino-4,4’-dihydroxydiphenylmethane, 27 Diels-Alder, 23 Diffusion eddy, 123 molecular, 123
N,N,-Diethyl-m-toluamide, 92 Efficiency, 11 8 equation, 121 Eigenzones, 137 Electrophoresis, 212 Elution curve, 12 Elution gradient,59 Epichlorohydrine, 270
N,N-bis(Etoxycarbonylpheny1)pyromellitic diimide, 305 Eurochrom, 189
Index Fluorisil, 161 Free energy, 264 Function of mutual information (FUMI), 138 Functionality, 13, 16 average, 26 equation, 21 number-average, 29 possible, 28 practical, 28 weight-average, 29 Gel equation, 3 1 filtration, 260 permeation, 132,258,264 point, 3 1 Gigapore, 85 Halochromatographic distribution,4 Hydroboration, 15 Hydroxyapatite, 191 Injection heart cuttingdevice, 152 split, 152 “Invisible”method, 298 Isotherm, 12,163 Kieselguhr, 84 LiChrospher, 273 Macromonomer, 15 Macropore, 85, 117 Malodextrin, 187 Mean-field statistical thermodynamic theory, 52 Megapore, 85 Mesopore, 85, 117 Microbore, 1 4 4 Micropore, 85 Model Dimov, 78 displacement, 68 Eble, 163
Index [Model] Galushko, 73 Guiochon, 163 Knox, 163 Onsanger, 73 precipitation, 52 slitlike, 264 Snyder 57,63,65 Snyder-Soczewinski,205 two-layer, 71 velocity-profile, 126 Nodule, 115
Octyl-methyldichlorosilane,102 Oligoglucan, 187 Oligomer, 13 telechelic, 13 Oligopeptide, 13 Organolithium, 101 Osmometry vapor pressure, 39 Packing, 83 composite, 84 hydrogel, 27 1 inorganic, 84 macroheterogeneity, 87 organic, 84 pellicular, 83 porous, 83 semirigid polystyrene, 269 Zwitterionic, 108 Partition process, 81 Peak broadening, 282 capacity, 62,259 Phase, stationary, 11 Physicochemical index, 79 Plate concept, 287 height, 62, 124, 126 number, 56,62 theory, 283 Polarity scale, 130 Poly-alkylsiloxane, 105
Polyamic acid, 28 Polyimide, 28 Polymer, telechelic, 13 Polymeric resins, 112, 191 Polypropylene glycol, 35 Polyurethane, 16 Pore volume, 86 Porogen, 115 Porosity equation, 114 interstitial packing, 86 Prepolymer, 16 Pyromellitic anhydride, 28 Q factor, 276
Radius chromatographic, 266 gyration, 266 Rate theory,283 Reaction injection molding (RIM), 16 Recycle, gel permeation, 306 Relative retention, 163 Resin, 27 Resite, 27 Resolution, 60 definition of, 118 Retention index, 70,79, 132 Retention mechanism, 71 Retention theory,70 Retention time, 60,69, 117,259 Rhodoxantine, 9 Selectivity, 67, 118 Separation, chromatographic,3 Sephadex-75,270 Silane, 98 Silanization, 99, 100, 102 Silanol activity, 89,92 groups, 87,89,93 reactivity, 93 Silica, 84,87, 90, 102, 191,272 acid, 88 Siloxane bridge, 97 Solute, 2
344
Solvent regain, 114 selectivity, triangle concept, 131 velocity, 262 Solvophotic theory, 53,56 Spheron, 275 Standards broad MWD, 280 narrow MWD, 275 Stationary phase, 11 Statistical mechanical theory, 44 Statistical thermodynamic theory (see also BAMB), 46,50 Styrene-divinylbenzenecopolymer, 112
Index Telechelic, 14 Theoretical plate, 122, 123 Theory of Dill, 56 Theory of Golay, 148,149 Theory of Van Deempter, 125 Tiokol, 35 2,4-Toluylenediisocyanate,39 Trichlorosilane, 102 1,1,l-Trimethylol propane, 39 Valves, injection, 152 Vit-X, 273 Volumetric variance, 150 Xanthophyle, 89