Advances in Surface Acoustic Wave Technology, Systems and Applications Volume 2

(13)

This determines the wavenumber /3 as function of the frequency w; it is the dispersion equation of the system. The eigenmodes may be determined from Eq. (12). In what follows only the two most strongly resonating harmonics will be retained, yielding the coupling-of-modes approximation. 1.3. Coupling-of-modes

theory

The infinite system of linear equations, Eq. (10), is rigorous up the accuracy of the physical model in Eq. (1); no assumptions are made on the strength of the perturbation and on the amplitudes of the harmonics. There are two known approaches for reducing the infinite system into a finite one: Algebraic approach: the system is truncated by ignoring weakly interacting highorder harmonics, resulting in a reduced system consisting of from two to perhaps a few hundred harmonics. Numerical methods may be utilized to solve the truncated system. Differential approach: the truncated algebraic equations are linearized in /3 and transformed into linear differential equations. The first approach is accurate and allows physical details of particular wave types to be easily retained in the formulation. Consequently, it is the theoretical basis for many rigorous methods. As discussed in Section four, numerical simulations of periodic structures involving hundreds of harmonics are employed to determine the values of COM parameters. However, since the approach requires intensive numerical calculation, it is often impractical and rarely used in device modeling. The second approach is much more popular, since it describes the local changes in the amplitudes of a very limited number of interacting waves and thus, it allows the treatment to be approximately extended for nonuniform, finite structures. In this paper, where we consider surface-acoustic waves in a periodic grating, the perturbation may usually be assumed to be weak and the interest is limited to a small frequency range around the center frequency /o = v/2p. Then, although the coupling between the Floquet harmonics is usually weak, a few harmonics interact very strongly and dominate the field. Consequently, all other harmonics may be ignored or may be taken into account as small corrections. This is called the coupledmode approach, or the coupling-of-modes model. Let us consider in some detail the two ways of writing the coupling-of-modes equations; the algebraic and the differential approach.

7

874

V. Plessky & J. Koskela

1.3.1. Coupling-of-modes

equations in algebraic form

We now limit the consideration to a weak periodic perturbation, |£j| -C 1. Due to the perturbation, the wave field consists of coupled Floquet harmonics. Particularly strong coupling occurs if the wavenumber (3 is close to a multiple of the half structure wavenumber ir/p, /?«ra-,

neZ,

(14)

p such that /?_„ = / ? - « — « - / ? . (15) P This is the Bragg condition. It may be interpreted as the wave components ±/3 being reflected to each other; these reflections are called Bragg reflections. Below and in Section 1.3.3. the Bragg reflections will be shown to lead to a resonance and the formation of a stopband. The phenomenon of Bragg reflections giving rise to a stopband is another fundamental characteristic of waves propagating in a periodically perturbed medium. For frequencies close to the n t h harmonic of the center frequency, / « n / 0 = nj-,

(16)

the coefficients Koo and if r _ n> _„ in Eq. (12) are very small while the other diagonal elements remain considerable. For the assumed weak perturbation, this implies t h a t the amplitudes ifo and ip-n are large and consequently, that the two harmonics dominate the system. The other harmonics may be considered as small perturbation or be neglected. We limit the consideration to the most usual case with n = 1. Under the Bragg condition, the wave field is then dominated by the harmonics <po and +Ci*§*"%>-! = 0 ,

C i ^ e - ^ o + ((/3-27r/p)2-/c2 V : = «,

^

and the dispersion equation (13) assumes the form

(/?2-*2) ( V S T / P ) 2 - * 2 ) - (Ci*2,)2 = 0.

(18)

Equations (17) and (18) contain the coupling-of-modes theory in algebraic form. Solutions to the equations are identical to those of the COM equations in differential form, considered below. 1.3.2. Coupling-of-modes

theory in differential

form

To derive the COM equations in differential form, the perturbation is again assumed weak and the frequencies of interest are limited close to the center frequency

Coupling-of-Modes Analysis of SAW Devices 875 f0 = v/2p. Consider a field satisfying the Bragg condition (14), with the wavenumber /3 presented as a small deviation q from the crystal wavenumber ir/p: IT

/3 = - + « , P

(19)

P

The dispersion relation to be derived determines q as a function of the frequency shift from the center frequency. Retaining only the main harmonics, n = 0 and —1, the Floquet expansion in Eq. (7) assumes the form
+ tp-! e~i
(20)

The spatial variation of the field is governed by strongly oscillating factors e ± t , r x / P , whereas the factors e~lqx describe slow variations. Therefore, we define a variable transformation t o separate the strong phase oscillations from the slow variations as follows:
(21)

Substituting this Ansatz into the wave equation (1) results in a new differential equation for the slowly-varying fields R(x) and S(x). However, provided that the fields indeed vary slowly, d 2 i? d ^ W

<

„.idi?, ,

2i- — (x) p dx

(22)

and d2S. .

d^{x)

«

(23)

p dx

Under the assumptions (22) and (23), the l.h.s. of the loaded wave equation (1) may be approximated as

(I)

e (24)

. „.7rd5(a;); + | +2i -^p dx

+ k%S(x)- (-\

S{x) j e + ^ / P .

On the other hand, substituting Eq. (21) into the r.h.s. of Eq. (1) yields C{x)
e+ie'R(x)e-3i™/p

-Ci

((0R(x)-(1e+ie'S(x))e-i™/p

+

+ (CoS(x) - Cie - 4 *' R(x)) - Cie- i 9 r

9

S(x)e+3i*x'p.

e+i"x'p

(25)

876

V. Plessky & J.

Koskela

Comparing Eqs. (24) and (25) and retaining only the main harmonics, the loaded wave equation assumes the form of two coupled equations ( - 2 i ~

+ k20 - (jj

J R(x) = -(»k%R(x)

+ Cifcg e+ie'

S(x), (26)

( + 2 i ~ + *§ - (j)

J S(x) = +Ci*g e-»'R(x)

-

2

Cok 0S(x).

Re-organizing the terms, the equations may be expressed as dR(x) da: dS(x) da;

= — iSR(x) + iK,S(x), (27) = -IK*R(X)

+iSS(x).

Here we have defined a detuning parameter (28)

~ ~2w ~ 2p and a coupling parameter, the reflectivity K, —

CiP, .2 ^iflr _ " ~ Kn £

(29)

2?r

Above, in Eq. (28), k again denotes the loaded wavenumber. Close to the center frequency of the grating /o = v/(2p) , such that A; « 7r/p, 6 =

P_ 2TT

k+

k-1 P

(30)

P

and the reflectivity K may be approximated as a constant. Equations (27) and (30) form the COM model in differential form. 1.3.3. Eigenmodes

and dispersion curves:

stopband

We now proceed to study the eigenmodes of the periodic system. The coupling-ofmodes equations (27) constitute a pair of coupled homogeneous first-order differential equations. We look for solutions of the form R(x) S(x)

Ro So

(31)

Substitution into Eq. (27) yields algebraic linear homogeneous equations: J |

(S-q) RO-KS0 K*RQ - (S+q)

= 0

(32)

So = 0.

W i t h the definitions (28) and (29), this pair of equations is exactly the same as the algebraic COM equations (17). However, note that the differential approach contains the approximation (30), whereas none is required in the algrabraic approach.

10

Coupling-of-Modes

Analysis

of SAW Devices

877

n/p

()

Fig. 1. COM dispersion relation: the wavenumber q = q' + iq" as a function of frequency. Solid and dotted curve: real and imaginary parts, respectively. Dashed line: uniform loading.

Setting the determinant of the system to vanish, perhaps the most important result of the COM model is obtained: = ±/j2T"

Imq<

(33)

0.

This relationship determines the slowly-varying wavenumber q of the eigenmodes as a function of frequency; it is known as the COM dispersion relation. Including the fast spatial oscillations yields the corresponding physical wavenumber P = Q/2+q. Mathematically, both signs of the square root in Eq. (33) yield equal results. However, physically the imaginary part q" should always be chosen nonpositive, and the homogeneous solution be normalized as follows:

R{x) S[x)

£-iqx

q+S

+

B

q+S 1

,iqx

(34)

Here, A and B are arbitrary coefficients of the two eigenmodes. Both eigenmodes may be interpreted as combinations of an incident wave and a reflected wave. The choice of the sign in Eq. (33) guarantees that the incident wave does not grow in the direction of propagation. The reflected wave has a phase velocity opposite to the incident wave, and a relative magnitude equal to the amplitude reflection coefficient in an infinite array. The dispersion relation (33) is shown in Pig. 1 for finite reflectivity. The figure illustrates in detail the stopband phenomenon: for small values of the detuning the wavelength is close to the periodicity 2p, leading to the Bragg reflections discussed

11

878

V. Plessky & J. Koskela

in Section 1.2.2. Due to the reflections, the eigenmodes attenuate in their direction of propagation. The frequency range

f-fo /o

< ^

(35)

with pronounced attenuation is known as the stopband, manifested in Fig. 1 as the appearence of a strong imaginary component q" of the wavenumber. The width of the stopband and the attenuation are determined by the magnitude of the reflection coefficient K, with the imaginary part assuming a maximum value — |K| at the center frequency. For a large detuning the wavenumber approaches t h a t for the uniformly loaded case. However, note that the consideration here is limited to the vicinity of the first stopband. 1.3.4. Comment

on the

terminology

The terminology presented in this Section may be considered as established and commonly accepted in the SAW community. However, it should be emphasized t h a t (in an absolute majority of cases) the term coupling in this context refers to the coupling between identical modes counter-propagating in a periodic grating. Thus, terms like 'coupling-of-waves' or 'distributed reflector' would describe the phenomenology of the system better than the general term 'coupling-of-modes'. However, in some other cases, such as waveguide analysis, the periodical perturbation may result in a coupling between different waves in the system, for example between different waveguide modes—including those propagating in the same direction. For such systems the term 'coupling-of-modes' is more adequate. Occasionally one can also see a coupling between SAW modes of entirely different type, such as the conversion of LSAWs into Rayleigh waves in a periodic array of electrodes, 12 or a coupling between Rayleigh waves and Lamb modes. 3 6 These cases are also very satisfactorily described by the coupling-of-modes theory. 2. C O M M o d e l for Surface-Acoustic W a v e s This Section reviews the established coupling-of-modes formalism for surface-acoustic waves, which covers the excitation of waves via an external drive voltage V, and the current generation at the electrodes. Inclusion of parasitic effects such as resistivity and extensions for shear-horizontal waves are postponed to Section three. Extraction of the COM parameters from experiments and numerical simulations is described in Section four. 2 . 1 . COM

formalism

Consider a surface-acoustic wave device, for example the synchronous uniform oneport resonator depicted in Fig. 2, consisting of an electrode structure fabricated on the surface of a piezoelectric substrate crystal. A drive voltage V connected over the bus bars of the device excites waves. In reverse, the waves propagating

12

Coupling-of-Modes Analysis of SAW Devices 879 under the electrodes cause flow of the current I. Alternatively, in the absence of the conductive electrodes the model may also be used to describe a set of grooves etched on the substrate surface. 2.1.1. Coupling-of-modes

equations

Based on the preceeding discussion, we describe the wave field in the device through two counterpropagating waves, or 'modes',
%M ax dl(x) dx


-i (—-h)

da; =

+iK21

^+(x)e+i2™lv

= +ir)X ip+ (x) e+ivxlp

i2lrx

/P + ia.iVt

+ i (--i-y)
-i-Kx/p

ia2Ve+i*°/>,

(36)

+ iuC V

are obtained. Here, velocity v, attenuation parameter 7, capacitance per unit length C, and the generally complex-valued quantities K12, K21, « i , 0:2, f)i, and 772 are the COM parameters to be determined. Due to changes, for example, in the periodicity, metallization ratio, and electrode thickness, the parameters may vary along the length of the device. The fields are normalized to the power flow P such that P{x) =

\\
(37)

The coupling coefficients (reflectivities) K ^ and K2i> and the parameters 0^2 and 771,2 are not independent. The electric power consumed by the device at x is

Pel(x) =

4=

iffi,

^ ( ^ - V

l(x)

\/M\fh>w

flh #A>
.P-H

Fig. 2. Schematic synchronous uniform SAW resonator.

13

(38)

880

V. Plessky & J. Koskela

On the other hand, the increase of acoustic power at x is Pac(x) = ~(\
(39)

The difference between the electric and acoustic power is the net power loss Pi o s s . Substituting the COM equations into Eqs. (38) and (39) yields Pioss(x)

= Pei(x) -

Pac(x)

= 7 ( l ^ + ( z ) | 2 + \
-lm((K*12+K2l)9+(x)
-±Im((Vl+2al)p+(x)V*e+i™'r

(m-2a2')^(x)V*e-i™/'>y

+

(40) Since the phases of
iW*)=7(IMz)| 2 + b-(*)|2),

(41)

and we may indentify K\2 — K, K21 = — K* T?I = —2a*, and 772 = +2a2- Furthermore, the principle of time reversal states that the COM equations should remain invariant under complex conjugation with the substitutions R*(x) —>• S(x), S*(x) —>• R(x), I*(x) —• —I(x), V* —¥ V, and 7 —> —7. As a result we find ati=— a2=a. Let us assume that the structure has a constant mechanical periodicity, pitch, p, and introduce the slowly varying fields R(x) and S(x) as follows R(x)e-^xlv,



(42)

S(x)e+i7rx/P.

Define a detuning parameter as x

0 =

w

v

*"

p

•

27T(/-/0)

27 =

v

.

17.

(43)

The final COM equations assume the form '

dR(x) dx dS(x) da: dl(x) da:

= — iSR(x) + inS(x) = -in*R(x)

+ iaV,

+ iSS(x) - ia*V,

= -2ia*R(x)

- 2iaS(x)

(44)

+ IOJCV.

The system of equations (44) constitutes the core of the COM model for SAW devices. The independent parameters of the model are velocity v, attenuation 7, reflectivity K, transduction coefficient a and capacitance per unit length C. Various notations concerning the phase, sign, and normalization of the fields and the parameters appear in the literature, see the discussion in Ref. 37, but the physical

14

Coupling-of-Modes

Analysis

of SAW Devices

881

content of the model remains the same. The physical interpretation of the COM parameters is discussed in Section 2.3. 2.1.2.

P-matrices

Let us consider a transducer located in the region x = [xi,x2]- The slowly varying amplitudes R(x) and S(x) and the current density d/(a;)/da: are uniquely determined by the COM parameters and the boundary conditions: the drive voltage V and the amplitudes

Pn(f) Pia(/) PilU) P22(f) P 3 l ( / ) P32(f)

Pia(f) P23(f) Pw(f)

¥>+(zi)

(45)


The upper left 2 x 2-submatrix describes the scattering of waves entering into the structure from the outside: P n and P22 are the reflection coefficients, while P12 = P21 is the transmission coefficient. Due to normalization of the amplitudes to the power flow, the power reflection and transmission coefficients are obtained by taking the squared magnitudes of the coefficients for the amplitudes. In the absence of attenuation (7=0), power conservation requires t h a t | P n | 2 + | P 2 i | 2 = l,

and

| P 1 2 | 2 + | P 2 2 | 2 = 1.

(46)

-o-


\k


\l

-X


fi

b cp-(*2) y y e

X=XX

x=x2 Fig. 3. IDT as a black box with one electric port and two acoustic ports at x\ and X2. The P-matrix relates the current and the excited acoustic amplitudes to the applied source voltage and the arriving acoustic amplitudes.

15

882

V. Plessky & J. Koskela

The remaining components of the P-matrix are relevant only for transducers. T h e components P 1 3 and P 2 3 describe the excitation efficiency of the IDT. The components P 3 l and P 3 2 measure the current generated in the IDT by the arriving waves. The acoustoelectric components are not independent; for the peak-value fields used here reciprocity requires that P31 = - 2 P 1 3

and P 3 2 = - 2 P 2 3 .

(47)

The 33-component of the P-matrix, t h e admittance, describes the acoustic and electrostatic currents due t o the drive voltage V. If the device is symmetric, i.e., bidirectional, the components of the P-matrix may be made t o satisfy Pll=P22,

Pl3 = P23,

P 3 1 = P32,

(48)

with an appropriate selection of the reference planes X\ and £ 2 . For some special cases, such as uniform structures considered in Section 2.2, the fields may be found in closed form, but for the general case numerical methods have to be resorted to, see, e.g., Ref. 40. 2.1.3.

Cascading

The principal reason for introducing the P-matrix is its convenience in modeling devices consisting of several different substructures, such as IDTs, reflectors, grooves and absorbers. Based on the assumption of locality, the substructures are treated independently and they are described using P-matrices. Linking the acoustic and electric inputs and outputs, a model for the whole device may be obtained. As an example, consider two structures A and B, sharing one acoustic port and connected electrically in parallel, as shown in Fig. 4. The structures may be described by two P-matrices P A and P B , respectively. The rules for obtaining the net P-matrix were derived by Abbott et al.39 and they are quoted below:

1

~~ ^ 1 1 ^ 2 2

^ = r^A=^,

(so)

pB pB -r12-r21

P22 = P2B2 + -P2A21 'Inl^ i--PiW2' pB I pB pA p „ _ pA , pA M3 + * l 1-^23

Pl3 - P13 + Pl2 —,1

pr B pr A

(51) '

~ - ll- 22 pA 1 pA pB *23 + r22r] "23 "I" ^21 — pBpA •rll-r22 pB 1 pB pA pA 1 r pAr pB r r r p _ pA , pB , pA rr1 , pB ^23 \Zr 13 13 3 t~r -^11-^23 \\ 23 *23 +f •22 22+ + pBp A ""31 ~,•, pA pB pB " ^33 - -f33 + ^33 + "^32 " j11 pB pA ^31 pA Xr r - •*! 1-^22 ?Z \\

^^a+^TZ:.

16

/ro\

^

(53) (K.A\ l04^

Coupling-of-Modes

Analysis

of SAW Devices

883

n

pA ^


(p_(L) (i) ye/(or

Fig. 4. Cascading two structures with a common acoustic port and electrically connected in parallel.

The remaining two components are determined by the reciprocity relationships in Eq. (47). Another frequently occurring case is a one-port resonator consisting of an interdigital transducer surrounded by two identical reflectors, possibly separated from the IDT by gaps; if the gratings continue as per electrode the pattern in the transducer, the structure is denoted synchronous. For brevity, we assume that the transducer and both reflectors are symmetric and they are described by P-matrices P and Ps, respectively. Then, the admittance of the structure is Y = P33

tPfiPh i-pfl(p11 + p12y

(55)

Analytic formulas for arbitrarily cascading many identical P-matrices have been derived by Morgan. 4 1 For uniform structures these are not required in the COM theory since analytical solutions are available (see above), but the formulas are very convenient in more general cases where solutions do not exist in closed form.

2.2. Uniform

structure

In a uniform structure the COM parameters are constants. For this exceedingly important special case the COM equations form an inhomogeneous system of linear first-order differential equations. In this case, the general solution may be constructed as a linear combination of the solutions to the corresponding homogeneous equations and of a particular solution. These are interpreted as shorted-grating eigenmodes and as the excited field, respectively. As a consequence, the elements of the P-matrix are soluble in closed form, enabling extremely fast numerical device simulation. Here, we assume that the device length L = Np, where TV is the number of electrodes, and define the edges as Xi = 0 and X2 — L. Consequently, the physical and slowly-varying fields are equal at x = 0, but equal or opposite at x = L, depending on whether N is even or odd, respectively. 2.2.1. Shorted-grating

eigenmodes

The homogeneous part of the COM equations is obtained by omitting the excitation terms. The equations reduce t o the basic model of Eq. (27), interpreted to describe

17

884

V. Plessky & J. Koskela o

o

o

o A'+i

(a)

(b)

LeleetrodeJ substrate

<

V///X p

V///X

>

v. V7WX

UWoeTd

••I

M

V///X

.

V+2 V77YJ

substrate

-*x

Fig. 5. (a) Shorted-circuited and (b) open-circuited grating.

counterpropagating modes in a short-circuited (sc) transducer or grating, see Fig. 5. As discussed in Section 1.3.3, the solution is of the form in Eq. (34) and satisfies the dispersion relation in Eq. (33): 2

&(/) = v^-l«l -

The frequency region with the pronounced attenuation, 8 < \K\, is denoted as the stopband. Neglecting the attenuation parameter 7, the lower and upper edges of the stopband are found as the zeroes of Eq. (33):

(56)

Thus, the stopband is formed around the center frequency / o , and the width of the stopband is proportional to the reflectivity K; the normalized value Kp is the reflection coefficient for one period of the structure. 2.2.2. Open-grating

eigenmodes

In an open-circuited grating the electrode voltages are floating and the boundary condition is that the current density dl/dx must vanish locally? see Fig. 5. Setting the COM equation for current density t o vanish yields

"-isy^&M-

(57)

Substituting this into the remaining COM equations yields (

dR(x) da; dS(x) da;

2a*2 \ K* + —pr )R(x)

+i

(>-m

(58) S(x).

°Note that it is not the same as a open-circuited transducer, i.e. a transducer with the total current equal to zero.

18

Coupling-of-Modes Analysis of SAW Devices 885 These are the COM equations for an open grating. 2 5 They may be reduced to the usual form by defining an equivalent detuning parameter (59) and an equivalent reflectivity K+

2*.

(60)

Consequently, the dispersion relation assumes the form qoc = \/82oc-

Kc\2-

(61)

Details of the dispersion curves are considered in Section four. 2.2.3. Excited field The particular (forced) solution is easily found as 8a + Ka* V. 8a* +n*a

RE SE

82-\K\2

(62)

The solution is interpreted as the excited field, arising from the drive voltage applied to an infinitely long transducer. The amplitude of the excited field is proportional to the voltage and it depends on the detuning. The wavelength corresponding to this solution is always equal to 2p. The term in the denominator in Eq. (62) equals A 2 , the square of the COM wavenumber for the shorted eigenmodes. For a symmetric structure, K and a are both real and, depending on the sign of K, the amplitudes interfere constructively on one edge of the stopband (usually, at the edge with lower frequency) giving a rise to resonance, and destructively on the other edge. 2.2.4. General

solution

Based on the above discussion, the general solution for the COM equations in a uniform structure may be expressed as R(x) S(x)

R-(x) S.{x)

+A+

R+ix) S+(x)

+

RE(X) SE(X)

V.

(63)

Here V is the drive voltage, the subscripts (—) and (+) indicate the two shortedgrating eigenmodes, reducing to the counter-propagating waves in the limit of vanishing reflectivity, and the subscript E denotes the field excited. The solution is uniquely determined by solving for the coefficients A_ and A+ from the acoustic boundary conditions R(0) = ^+(0), (64) N

S(L) =

(-1) ^(L),

19

886

V. Plessky & J. Koskela

0.11'\ ' ; / ! . ' J

M^_j

-4

u

-

3

-

2

-

A/// 0

1

0

1

2

[K/I/W]

Fig. 6. Magnitude of the reflection coefficient |fn|=|P22| for various normalized device legths KL as a function of the normalized frequency Af/fo-

where
P-matrix

For an interdigital transducer, or an electrically shorted grating, the components of the P-matrix describing scattering assume the following forms:

Pi

-P22 =

in* sin(gL) q cos(qL) + i8 sva(qL)' q cos(qL) + i8sin(qL) IK sin(qL) q cos(qL) + iS sin(gL)'

(65)

The frequency dependence of the reflection coefficients is illustrated in Fig. 6. For electrically open reflectors, the quantities 8, K, and q should be replaced with the corresponding variables given by Eqs. (59), (60), an (61). Since 8oc and KOC vary slowly with frequency, the frequency behaviour of the reflection coefficients is similar t o that in Fig. 6.

20

Coupling-of-Modes Analysis of SAW Devices 887 For the excitation efficiencies one finds 13

sin(qL/2) qL/2

~

_ P23--(-l)

i\N T

sin

{5a* + K*a) sin(gL/2) - ia*q qcos(qL)+iSsin(qL) 2

(g-^/ ) (Sa + Ka*)sm(qL/2) qcos(qL) + qLj2

cos(qL/2) '

iaqcos(qL/2) iSsm(qL)

The total current I is integrated from the active area, ex ^2 Jxi

dl(x) Ax, da;

(67)

Due to the reciprocity, fti

= -2Pis,

^32 = - 2 P 2 3 .

(68)

The element P33, admittance, consists of two components: P33=P£+P3E3.

(69)

The first term on the r.h.s. represents currents due t o the eigenmodes generated by the drive voltage and reflected from edges of the transducer: 4 ((S2 + \K\2) \a\2 + q3 qcos(qL) +

osc _ 33 ~

4» (S\a\2 + JR(/c*a2)) q3

25X(K*a2))(l-cos(gL)) i6sm(qL)

qsmjqL)

(70)

q cos(qL) + iS sin(qL)

whereas the second term, T>E P

T

,.S\a\2+fflK*a2)

33 = ~L ±1 '

'J2 _ ^

| 2

. „

T

+ IUJCL,

(71)

describes currents related to the excited field. For bidirectional uniform structures, the phases of the reflectivity K and the transduction coefficient a cancel each other, such that K*a2 = ± | / t | | a | 2 . In this case, K, and a may be chosen real-valued by simple translation of the coordinate system, see below. Consequently, the components of the P-matrix may be expressed in the form _ P23 =

sin(gL/2) (<5 + K) sin(gL/2) — iq cos(qL/2) qL/2 qcos(qL) + iSsm(qL) ' N (-l) P13,

(72)

while the admittance terms assume the forms = 33

4a2{8+ q3

K) (6 + K) (1 - cosjqL)) qcos(qL)+iSsm(qL)

21

iqsmjqL) (

'

888

V. Plessky & J. Koskela

Fig. 7. Resonance-antiresonance pattern in the admittance of an infinitely long periodic transducer. Solid and dashed curve: real and imaginary parts, respectively.

and pE

_

••33 —

4c^ L + iujCL. '7

(74)

0 — K

In long structures, the latter term dominates; the resulting admittance is illustrated in Fig. 7. A strong resonance is formed at one edge of the stopband due to constructively interfering eigenmodes; the other edge of the stopband cannot be observed since the interference is destructive. Furthermore, an antiresonance is created at the frequency where the imaginary part of the admittance crosses zero. Due to attenuation always being present in physical devices the resonance peak is of finite width and height. For more details the reader in directed to Sections 4.1 and 5.2.1, dedicated to synchronous uniform resonators. 2 . 3 . COM

parameters

The differential equations forming the COM model (44) cover the electric excitation, propagation, and mutual reflections of counterpropagating, plane-wave like acoustic modes in a ID effective continuous medium, as well as the generation of electric currents. These phenomena are quantitatively measured through the external COM parameters, which are to be determined by and based on the physical properties of the structure, such as materials, crystal cut, aperture, metallization ratio, and the shape of the electrodes. They also depend on the frequency and temperature. In the equations (44), most COM parameters have the dimensions of densities. For example, the reflectivity K may be interpreted as reflectivity per unit length. This is not very practical. Instead, it is convenient to define the normalized parameters displayed in Table 1, interpreted as parameters for a unit period of length An (e.g., An = 2p for a single-electrode IDT). These ideally remain scale-invariant constants. In practice, the parameters deviate because of waveguiding, parasitics,

22

Coupling-of-Modes

Analysis

of SAW Devices

889

Table 1. COM parameters normalized to the aperture W and the wavelength at the center frenuencv An. quency Ao

parameter velocity reflectivity transduction coefficient

symbol v Kp — K\Q ap = aAo

normalized transduction

an= ap/ J^-

attenuation capacitance normalized capacitance

7 P = 7A0 Cp = CXQ Cn = Cp/W

dimension (SI) m/s £2 - 1 ' ft-1/2 Neper/ Ao F F/m

and other effects. Since the COM theory is phenomenological, the values of the COM parameters cannot be determined from the theory itself—they must be introduced from outside. Much work has been done to determine the characteristics of SAW propagation and excitation in periodic arrays of thin (h/\o ~ 1%) electrodes 2 5 ' 4 2 , 4 3 , 4 4 ' 4 5 ' 2 8 using perturbation theory, variational approach, or similar methods. However, relative electrode thicknesses h/\o as high as 10%, corresponding to height/width ratio of about 40%, are now used in low-loss R F filters. Such electrodes can hardly be considered thin and the results of perturbation theory are not sufficiently accurate for design applications. Nevertheless, the relations obtained are still useful in providing physical estimates for the values of the COM parameters and the device sensitivity. For this reason, we will briefly quote some main results; an interested reader is directed to the references, for example the discussions in Refs. 25, 27,46, 28. Modern methods for COM parameter extraction, based on experimental measurements and rigorous field-theoretical simulators, are considered in Section 4. 2.3.1.

Velocity

SAW propagation in the absence of reflections is determined by the wave velocity v and the attenuation parameter 7. Electrical and mechanical loading by the electrodes (aluminium is commonly used) and waveguiding, usually lead to frequencydependent slowing of the wave. The velocity change due to the loading by a periodic array of thin electrodes may be presented as a power series expansion on the relative electrode thickness ft/Ao: Av Av h Av

A)+...

(75 ,

The expansion coefficients depend on the geometry of the electrodes. The higher the relative electrode thickness, the more terms are required in the expansion; here, we consider only the first three. The first term in the r.h.s. is negative and it describes slowing of the wave due to the electric loading. 47 Conductive electrodes on the surface short-circuit electric

23

890

V. Plessky & J. Koskela Table 2. Parameters for loading by Al electrodes, a/p — 0.5, / J / A O = 0 - 1 %

substrate

v0 [m/s]

ST-quartz X-112°Y-LiTa03

3158 3301

(*). -0.04% -0.33%

f—)

R,

Rm

-0.10 -0.053

-0.04% -0.32%

-0.54 -0.43

Materials parameters for quartz and LiTa03 from Refs. 50,51.

fields, decreasing the energy flow in the wave and consequently, velocity. The term is roughly proportional to the piezoelectric coupling coefficient. The second and third terms describe the linear shift due to the mechanical loading and the so-called energy storage effect, 44 ' 48 respectively. The energy storage effect is present also in periodic arrays of grooves, where the mass loading is absent and the first order effect is negligible. For aluminum electrodes in quartz, LiNbC>3 and LiTaC>3 both terms are usually negative. Table 2 gives some idea of the values, extracted 4 9 from rigorous simulations. When the velocity of the surface wave is much higher than that of bulk shear wave in the (thin) aluminum electrodes, the linear term in the expansion dominates, and the SAW velocity decreases almost linearly with increasing electrode thickness. This is the case, for example, in rotated Y-cut LiNb03 and LiTaOs. On the other hand, if the velocities are close, such as in ST-quartz and 112°-LiTa03, the linear shift is very small in comparison to the energy storage effect. In some cases, such as in 45°XZ-cut lithium tetraborate, 5 2 the first term is positive while the second term in negative, resulting first in an increase and then in a decrease in the velocity with growing metal thickness. 2.3.2.

Attenuation

The normalized COM attenuation parameter 7 P is measured in Nepers/wavelength (1 Neper « 8.6859 dB). Attenuation is also commonly measured in dB/fis: 7 « 8.6859 • 7 P /

[dB/fjs],

(76)

where 7 P is attenuation in Neper/wavelength, v is the velocity in m / s and / is frequency in MHz. Note, however, that the parameter includes all acoustic energy loss mechanisms in the device and that it itself also depends on frequency. There are many contributions to the SAW attenuation, such as • the interaction with thermal phonons, inherent to crystalline material and unavoidable at finite temperatures • scattering on surface and near-surface defects • air loading (or loading by another adjacent medium) • acoustic attenuation in metal fingers • acousto-electric interactions

24

Coupling-of-Modes Analysis of SAW Devices 891 • diffraction • coupling with other, parasitic modes such as bulk waves. In practice, it remains very difficult to reliably determine the attenuation parameter in electrode structures. Due to the Bragg reflections it is difficult to accurately measure the attenuation close to the stopband. Furthermore, the attenuation is very sensitive to the quality of the crystal surface (especially at GHz frequencies), and it depends on the crystal cut as well as the structure and geometry of the electrodes. Due to the presence of parasitic loss mechanisms such as coupling with parasitic modes such as BAWs, the attenuation may depend strongly on frequency. Finally, attenuation manifests itself also in the excited field as a factor limiting the amplitudes of the waves and determining the Q-factor of the resonance arising at the edge of the stopband. Recently it was discovered 53 ' 54 t h a t the coupling of the LSAW with slow shear BAW in rotated Y-cut LiTaC>3 may be drastically reduced by an optimal selection of the cut angle and the thickness of the aluminum electrodes. For the thickness h/\o « 8%, minimal losses are attained for cut angle of about 42°. However, a problem remains, although the attenuation for LSAW should be diminished (in theory, to less than 2 ' 1 0 - 4 dB/wavelength, or 2.3-10 - 5 Neper/wavelength), electrical measurements of test devices in the 1 GHz frequency range yield attenuation parameters that are almost 2 orders higher (about 10~ 3 Neper/wavelength). The reasons for such high attenuation are not clear for the moment. Besides the other mentioned mechanisms, also waveguide losses are expected to contribute: although the attenuation is minimized for X-propagation, the losses increase radically for propagation directions offset from the crystal X-axis. 2.3.3.

Reflectivity

The magnitude of the normalized reflectivity, KP, is equal to the absolute value of the reflection coefficient per period, and it determines the relative width of the stopband, A / / / O = | K P | / 7 T . For many important substrates, including ST-cut quartz, 36°-42°YX-cut L i T a 0 3 and 64°-YX cut L i N b 0 3 , the sign of KP is negative, but it may be also positive, e.g. for thick aluminium electrodes on 128°YX-cut LiNb03. The phase of K yields the reflectivity center of the period, see below. The reflection coefficient for a thin electrode of width a in a periodic array has been studied by many authors. 2 5 ' 4 2 - 4 3 ' 4 4 - 4 5 ' 5 5 ' 5 6 ' 4 8 ' 5 7 ' 5 8 It can also be represented as a series expansion on the relative electrode height h/\o: r = inp = iKp/2 « iRe + ii? m sin(7ra/p) — . Ao

(77)

The first term describes the reflectivity due to the piezoelectric loading by an ideally reflecting finger. The term depends on the width of the electrode and it is proportional to the piezoelectric coupling coefficient, see the comprehensive discussion in Ref. 46. The second term is due to the mechanical loading and it includes mass

25

892

V. Plessky & J. Koskela

loading and stress generation due to film deformation. Even film of the same material as the substrate (that is: an array of grooves) creates additional stresses, and the reflection coefficient is finite in the first order on H/XQ. Example values for Re and Rm are shown in Table 2. However, the formulas should be used with caution, keeping in mind that perturbation theory applies only for small perturbations and weak piezoelectric coupling. Numerous other configurations have been studied with perturbation theory. We will mention one interesting result: for oblique incidence of Rayleigh SAW from a reflectangular strip on an isotropic medium, the reflection coefficient is of the form 59 r = i/2 [ 1 - 4 ( — ) sin 2 6» j s i n / V - c o s t f j ^ - .

(78)

Here, 6 is the angle of incidence, and up. and Vt denote the velocities of Rayleigh wave and transverse bulk-acoustic wave, respectively. One can see that there is a Brewster angle, 6* = arcsin(v R /2w t ), between 25.9°-28.5°, for which the first order reflection coefficient vanishes. For the case of normal incidence (8 = 0), the result reduces to that in Eq. (77). 2.3.4. Transduction

coefficient

The normalized transduction coefficient, ap, measures the excitation of waves due to piezoelectric coupling in a unit cell of length Ao, which in the simplest case is formed by a pair of electrodes. It has the dimension of f 2 - 1 / 2 . For a very short transducer consisting only of one period, from Eq. (66) 13

+ia*,

P 2 3 « -iap.

(79)

Thus, the absolute value \ap\ is equal to the magnitude of waves generated by the period under a drive voltage of unity, while the phase of the coefficient defines the location of the transduction center, see below. As it was shown by Abbott, 2 7 the transduction coefficient ap is proportional to the piezoelectric coupling coefficient K and to the square root of the aperture W. With VR being the Rayleigh wave velocity and £s(°o) denoting the static permittivity of the substrate, 2 7 , 6 0

^0(¥) e s ( o o )

(8o)

with the factor a being of the order of unity. To remove the dependence on aperture, the normalized value an — ap/^W/Xo is defined. It depends on the strength of the piezoelectric coupling and on the metallization ratio. For LSAWs on LiTa03 and LiNb03 substrates, the total mass of the electrodes also has an influence as well. Typical values of an are about 3.3-10 - 5 fi_1/2 in quartz, and 80-110-lO - 5 ft"1/2 for LSAWs in L i T a 0 3 and L i N b 0 3 .

26

Coupling-of-Modes Analysis of SAW Devices 893 2.3.5. Capacitance

parameter

The normalized capacitance parameter, Cp, measures the electrostatic storage of energy in the structure per unit period. Due to the long range of electrostatic forces, the capacitance actually depends on the length and aperture of the structure, but in long transducers the value is practically proportional to the device length. Therefore it is convenient-especially in device design-to introduce normalized capacitance Cn = Cp/W, t h a t is: capacitance per period (electrode pair) and per unit length of aperture. If the aperture is expressed in micrometers, the values for LSAW-cuts in LiTaC>3 and LiNb03 substrates are about 48-64-lO" 5 p F / p m . For materials with weak piezoelectric coupling, such as quartz, the COM capacitance parameter Cp is very close to the static capacitance of the transducer per electrode pair. For this reason, the confusing term 'static capacitance' is frequently used in the literature. However, for strongly piezoelectric materials the situation is more complicated. 61 It is more appropriate to consider Cv as a parameter to be fitted so as to most accurately describe the capacitive contribution to the admittance in Eq. (71) in the frequency range of interest. 2.3.6.

Unidirectionality

In Section 2.2 the components of the P-matrix for a uniform structure were found to depend on the phases of the reflectivity and the transduction coefficient, 8T = LK and 6e = la, respectively. The phases depend on the locations of the reflectivity and transduction centers of the considered period, and they are connected to the directionality of the structure. Consider the period shown in Fig. 8, with reflectivity and transduction coefficients KP and ap, respectively, and with terminals located at Xo ± Ao/2. The reflectivity center xT is defined such t h a t the period is imagined t o be replaced by a symmetric reflector with reflectivity r and located at the reflectivity center. Between the terminals and the reflector the waves are assumed to propagate with some reference wavenumber, say fco = u/v. Since the reflected waves travel the distance between the terminal and the reflection center twice, the reflection coefficients P n and P22 may be expressed as p _ re—iko2(xr—xo+Ao/2) PP 2 2 =re -ifco2(x 0 +A 0 /2-a :r )_ 22 On the other hand, from COM we obtain P n « i/c* and P22 « inp. comparison shows that 0 r = 2k0 (xT - xo) + nir, such that

f P n = ±i|/«P|e-i2fc»(^o),

\ P22 = ±iK|e+ i 2 f c °^°>.

(81) Careful (82)

(S6)

The excitation center is defined in a similar fashion as the reflectivity center: waves are imagined to be excited at the excitation center, from where they propagate to

27

894

V. Plessky & J. Koskela

rl=2£ 0 (Xr-*l) ''<


>v '•• S~

!"*

1

<|)r2 = 2 ^ o ( ^ 2 - ^ r )

"

*

-M X]=XQ-XQI2

xt

XQ xt

e2=£o(*2-*e)

1

-+x

X2=X0+XQ/2

Fig. 8. Reflections and wave excitation in a unit period, interpreted as wave propagation through the centers of reflectivity and transduction.

the terminals. Then, 6e = k0 (xe - x0) + nw, such that

P13 \

p23 =

=±i\ap\e-iko(x'-^°) ^i\ap\e+iko<-x°-^°\

(84)

(85)

If the transduction and reflection centers coincide, the period is physically symmetric, and any phase differences occurring between the terminals are entirely due to the terminal positions. The period is then called bidirectional. In the expression for admittance, Eq. (71), this is manifested by the cancellation of the phases in the term 5R(K*OJ 2 ). Actually, in this case both KP and ap may be made simultaneously real-valued by translating the center of the period to the reflectivity center, such that xo = xT = xe. On the other hand, if the reflectivity and transduction centers do not coincide, the positive and negative directions are physically different. The period is then called unidirectional. Unidirectionality is inherent to some substrates, 6 2 whereas in other substrates it may occur because of specially designed asymmetry of the IDT structure. 6 3 , 6 4 This phenomenon is used t o construct single-phase unidirectional transducers (SPUDTs), where wave excitation in one direction is favoured over the opposite direction. 2.4.

Limitations

The simple system of linear equations (44) forms the core of the COM model. The equations take into account the multiple reflections and acoustoelectric interaction between the SAW and the charges on electrodes. Because of this the equations allow the modeling of a large variety of SAW devices. In spite of its intrinsic simplicity the COM model can be astonishingly precise for narrow band devices, provided that the explicit COM parameters are determined accurately. Meanwhile, one should remember that the simplicity of the COM equations requires numerous approximations. We repeat here some of the main limitations: • The surface acoustic wave is describe by a single quantity - the amplitude normalized to the power flow. The spatial structure of the wave is supposed to

28

Coupling-of-Modes Analysis of SAW Devices 895 remain independent of location, wavenumber and frequency. This assumption is strongly violated by, for example, surface transverse waves. • As discussed in Section 1, all interactions, reflections, and perturbations of the SAW must be small. This restriction is not so important in practice because the piezoelectric coupling tends to be small. In most of the cases of practical interest the finger reflectivity also remains small. • The equations are based on the periodicity of the structure. Abrupt changes in the periodicity, occurring for example, at gaps between transducers and reflectors and at the ends of structures, cause effects such as phase changes, additional reflections and scattering into bulk waves, which are beyond the COM model. • The COM equations (44) describe only the two identical counterpropagating waves. If there are more interactions in a system (e.g. synchronous generation of bulk waves, or the counterpropagating waves are not identical), the model is not valid any more. Problems occur, for example, for surface transverse waves, and (although not very strongly) for leaky SAWs. • To remove the fast variations from the amplitudes, slowly varying amplitudes were introduced by removing factors exp(±iirx/p). In principle, this is not a limitation, but it requires that careful attention is paid to the reference planes and interfaces between structures with different properties. Furthermore, the COM model treats the structure as a continuous medium, which in optimization routines may result in meaningless configurations—for example, in a device consisting of a noninteger number of electrodes. One simple approach to solve these problems is to limit the total length of transducers and gratings to even multiples of the pitch, while treating gaps separately. • Accurate results are only obtained in a narrow frequency range. The frequency dependence of the COM parameters must be taken into account when modeling filter characteristics over a wide frequency range. Phenomena such as generation of bulk waves, coupling to bulk modes, and the spatial harmonics present at higher frequencies influence the device characteristic but they are excluded from the COM model. • Although the COM model as presented here remains one dimensional it is nevertheless applicable to waveguide modes, provided that their structure is the same for counterpropagating modes. That means that all 2D effects, such as radiation into busbars, coupling to obliquely propagating waves, etc., are out of the sphere of the COM model. • Finally, there exist parasitic effects not related to the surface interactions: acoustic reflections from the bottom of the crystal, resistive losses, stray capacitances due to the bus bars and other metal layers, inductances of the

29

896

V. Plessky & J. Koskela bond wires, and effects due to the package geometry. Usually, these effects are taken into account via equivalent circuits.

Some of these limitations will be discussed in detail in a Section 3, which is dedicated to modifications to the model. 2.5. Comparison

with other

models

The main advantage of the COM model is that it allows the admittance to be calculated while providing an accurate description of multiple reflections of the counterpropagating waves. However, there are also other possibilities to do the same. In the mixed-matrix model, 1 ' 3 8 the medium is presented as a set of cells, each described through a separate P-matrix. Clearly, the COM model may be seen as one way to derive the P-matrices, or this mixed-matrix approach can be seen as another way t o solve the COM equations, replacing the differential equations by finite differences. The possibility of varying the properties of individual electrodes is very useful and it is widely practised in the design of sophisticated resonant SPUDT devices 65 on quartz. Many authors successfully use equivalent circuit models, 1 where SAW propagation is modeled as EM signal propagation in a transmission line, the free surface and metallized area being described by different impedances of the transmission line. The signal generation due to an applied voltage, the current generation in the load as well as losses and energy storage effects are included. Connection of mismatched transmission lines accounts for multiple reflections. Equivalent circuit models are a bit archaic but they have the strong advantage that they can be easily implemented in circuit simulation tools. In all these models the propagation, interaction and coupling parameters are introduced phenomenologically, the COM model being the most consistent in this aspect. The problem of accurate determination of parameters is practically the same for all models. The parameters depend on the geometry and the physical properties of the electrode structure and substrate. Whatever model is used, technological variations result in inaccurate determination of the parameters and in finite precision of the design. 3. I m p r o v e m e n t s a n d Modifications of t h e C O M M o d e l The COM model has been widely applied in the design of devices based on different types of waves, substrate materials, and electrode structures. In many cases the model works successfully, but some difficulties have been encountered and, consequently, modifications have been and are being introduced. We divide the attempts to improve the COM model into two groups: 1. Patch improvements, which add some specific useful features, or account for some secondary effect, without changing the main COM equations (44).

30

Coupling-of-Modes Analysis of SAW Devices 897 2. Radical changes of the model—the case of shear-horizontal surface waves.

3 . 1 . Patch

improvements

3.1.1. Finger

to the COM

model

resistivity

The finite resistivity of the electrodes has an effect on the device response by 1) introducing losses via conversion of energy into heat, 2) leading to a nonuniform voltage along the device, 3) causing additional dispersion and 4) leading to nonuniform excitation distribution along the aperture. As discovered by Wright, 2 6 mechanisms 1-3 may be incorporated in the COM formalism via a straightforward substitution V _ V - , * £ > ,

<«>

whereas the mechanism 4 must be taken into account by determining the values of the transduction coefficient a and resistance for unit length r appropriately. After some manipulation the equations may be cast into the form dR(x) dx dS(x) —i-i dz dl(x) dx

.(. \ =-i _

2ir\a\2 \ „ , , 1+iioCr J

lira2 \ 1+iwCr J

./ \

cu

,

iaV 1+iwCr'

.( „ 2ia*2r \ „ , , ./. 2i\a\2r \ „ . , —) R(x) + i[5 ' ' S(x) K*H K V 1+iuCrJ V 1+iuCr) ' 2ia*R(x) 2iaS(x) IUJCV l+iu;Cr 1+iujCr 1+iwCr

ia'V —, 1+iuCr'

,e_. (87)

The parameter r = RXo, where R is the Ohmic series resistance of the period. Theoretical evaluation of the period resistance requires electrostatic analysis. 6 6 ' 4 6 In a single-electrode transducer it may estimated as 2W «=-

S r

PD

(88)

where prj is the square resistivity of the metal, a is the width of the electrodes and W denotes aperture. If the resistivity is small, the effect on dispersion characteristics and excitation remains negligible, and the additional losses may be taken into account via an external series resistor. On the other hand, in the limit r —>• oo the current vanishes, I —>• 0. Physically, this limit corresponds to an electrically open-circuited grating, i.e. an array of floating electrodes. The equations reduce to those in Eq. (44), obtained in Section 2.2.2 based on charge neutrality considerations. 3.1.2. Velocity dispersion, backscattering and bulk-wave

generation

The accuracy of the COM model is basically limited to a narrow frequency band around the resonance. However, the requirements on SAW filter performance are not limited to the passband of the device, but usually cover a much wider frequency

31

898

V. Plessky & J.

Koskela

range which seems t o have a tendency t o further increase. Rather unexpectedly, COM is often found t o work adequately even over a wide frequency range. There are a few reasons for this: • Over a wide frequency range the filter behavior is more dependent on electrical characteristics (such as capacitancec of the transducer, connectors, and package, and the inductances of bonding wire) than on acoustic activity. Consequently, the accuracy of COM is not so important. • If only Rayleigh waves are generated, COM predictions of effects such as weak reflections in a periodic grating remain fairly accurate even at large frequency detunings. • Finally, in many cases the effects due t o bulk wave generation, appearing a t high frequencies, are relatively weak and manifest themselves only outside the passband. A few simple extensions 35 can be introduced into the COM model to further improve the agreement with the measurements. If the frequency range of interest is rather large, the wavelength A and thus, the relative dimensions of the structure do not remain the same. This results in dispersion, i.e frequency-dependent changes in the wave velocity and other COM parameters. In principle, all COM parameters may have a smooth dependence on frequency. However, the most visible effects result from velocity dispersion. Typically, the velocity decreases with an increase in the relative electrode thickness h/X. For low frequencies the relative thickness is smaller than the value in the stopband, H/XQ. Consequently, the theoretical velocity is too small and the ripples below the stopband are predicted by the model a t too low frequencies. At high frequencies the situation is opposite: the theoretical velocity is too high and the simulated peaks are predicted at too high frequencies. So, the velocity dispersion causes "accordion"-type mismatch between the theory and measurement. This mismatch may be easily corrected by the introduction of dispersion in the wave velocity as follows:

v(f)=vo(l-D±^y

(89)

Here /o, Ao, and VQ are the frequency, wavelength and velocity of the wave, respectively, measured at the center frequency of the Bragg stopband, and D is a parameter of the order of unity. Note that the velocity shifts are reflected in the eigenmode dispersion equation (33), which assumes the form

2 w

«W(foK) - -

90

<>

At frequencies above the stopband, incident leaky surface-acoustic waves and surface transverse waves are strongly scattered into bulk-acoustic waves, 3 2 , 6 7 resulting in pronounced attenuation of the surface wave. The phenomenon is considered

32

Coupling-of-Modes Analysis of SAW Devices 899 in detail in Section 3.2, but the increase in the attenuation may be roughly included into the COM model by adding an appropriate term to the attenuation parameter. 3 5 Furthermore, at frequencies close to and above the frequency / B = v&/2p, synchronous generation of bulk waves occurs in the transducer. In resonators this may be the dominant loss mechanism at high frequencies, / > / B , and it results in a square-root type increase in the conductance and attenuation of the wave. To take the effect into account in the COM model, empiric terms may be added to the attenuation parameter and the conductance of the device, such that leff

= 1 + 7scattering(/) + 7 B A w ( / ) .

(91)

and y ( / ) = l c o M ( / ) + GBAw(/).

(92)

35 68

Any appropriate step functions ' can be used to describe the onset and magnitude of scattering and BAW generation and, if necessary, the transition regions. For LSAWs on LiTaOs substrate the typical increase in attenuation is about 1 order of magnitude. If the aperture of an electrode structure is narrow, the transducer behaves as a waveguide. As far as equivalent counter-propagating modes are considered, there are no difficulties for the COM theory. However, changes in the phase velocity of the waves inside and near the stopband can result in curious behavior of the guided modes: in some cases the waveguiding effect can disappear at the upper edge of the stopband. 3 1 3.2. Shear-horizontal

waves

The coupling-of-modes model has been remarkably successful in describing devices based on conventional Rayleigh-type surface acoustic waves, with a dominantly sagittal polarization and a velocity substantially slower than those of bulk waves. However, the model is less suitable for shear horizontal surface acoustic waves, such as surface transverse waves and the commercially important leaky surface acoustic waves in rotated Y-cut LiNb03 and LiTa03 substrates; the latter are used in virtually all R F SAW bandpass filters. A characteristic of shear horizontal waves is that the velocity is close to a fast shear bulk-acoustic wave. In some sense, the shear horizontal waves may be interpreted as fast shear BAWs localized to the surface by some physical mechanism, such as an interaction with the electric fields in piezoelectric substrates (BleusteinGulyaev waves, 69 leaky SAWs in rotated Y-cut L i N b 0 3 7 0 and L i T a 0 3 7 1 ) , mass loading (Love waves 72 ), or loading by periodic electrode structures (surface transverse waves 73 - 74 ). The localization depth is determined by the small difference in the velocities of the surface and bulk waves, and (in contrast to Rayleigh waves) it depends strongly on the strength of the surface perturbation. For leaky waves in LiNbOa the localization depth is determined by the high piezocoupling, and the stopband is well separated from the bulk wave generation

33

900

V. Plessky & J. Koskela

frequency region. However, for LSAWs in LiTaOs the upper edge of the stopband may extend close to the threshold fB = vB/2p, and for STWs in quartz it may even exceed the threshold. Consequently, small changes in the velocity inside the stopband result in a strong change of the localization depth, and may eventually delocalize the surface wave into a bulk wave. Therefore, the application of the standard COM model is, from the very beginning, questionable. Alternative formulations have been suggested by a few authors, 7 5 ' 3 2 ' 3 3 ' 7 6 ' 7 7 in most cases directly based on the Floquet theorem and the algebraic form of COM equations. 3.2.1. Dispersion

relation

Historically, approaches which describe shear-horizontal waves have typically considered STW propagation in a periodic grating on a quartz substrate and utilized the Floquet expansion and the Datta-Hunsinger boundary conditions, 43 see, e.g., Refs. 75,78. This approach leads to a system of equations, the solutions of which yield the dispersion relation of the eigenmodes; the modern F E M / B E M simulators are based on the same concept, with a more sophisticated selection of the degrees of freedom and rigorous numerical treatment of the mechanical boundary conditions. Danicki 79 derived a phenomenological model for the strip admittance of a periodic array, thus enabling the analysis of excitation. Based on these works, the propagation of shear horizontal surface-acoustic waves in a periodic grating is well understood. The dispersion characteristics are well encapsulated in an algebraic model due to Plessky. 32 Let us consider BleusteinGulyaev waves (BGW's) in a semi-infinite substrate, shorted electrically by a metal layer with a periodic mass density of the form in Eq. (2). Let us search for a solution of the form u(x, z) = u+e-^x+K+z + u_e-i^-^x+K-z. (93) Here, u+ and u_ represent the amplitudes of the incident and reflected wave respectively, and f3 = Q/2 + q is the wavenumber of the incident wave. The case when the reflected wave is transformed into a bulk wave scattered in the opposite direction is automatically included. The factor K± denotes the localization constant K± = ^ ( Q / 2 ± g ) 2 - A | ,

(94)

where kB = UJ/VB and vB denotes the bulk-wave velocity. The sign of the square root is chosen such that Re y/x + iy > 0,

{ Im y/x + iy > 0,

x > 0, x <0

,g5x

Substituting the Ansatz into the boundary conditions, coupled-mode equations of the form „

(*--.o(f-*)-2£of)«- = 2^fM+,

34

(96)

Coupling-of-Modes Analysis of SAW Devices 901 are found. 59 Here, 770 is the piezoelectric coupling constant and parameters so and ei describe the uniform mass loading and the coupling between the counterpropagating waves, respectively. Setting the determinant of Eq. (96) to vanish, we obtain the dispersion equation

(*+-„„
v

/ ( Q / 2 ± 5 ) 2 - ( Q / 2 + A ) 2 » ^/Q/2 y/2(±q - A)

(99)

and treat the electrical and mechanical coupling terms as constants: 2q

/2ABV

v

\ v /

£l

/2fcB\

2

[2 v v

(10Q)

/T

{-Q-J " V Q"

For rotated Y-cut quartz, approximate theoretical expressions for the dispersion parameters r\ and e have been derived in closed form based on physical arguments. 7 6 Within the approximations, the dispersion equation reduces to (y/2(+q-A)

- r,) ( 7 2 ( - s - A ) - v ) = \ef .

(101)

The approximate dispersion equation (101) may have zero, two or four solutions. However, one may show that, provided q is a solution, it satisfies q = ± J A2 - I ( j £ | 2 ±

2

Vo]/2\e\

-ri2-4A\

(102)

In most cases the physical solutions correspond to the positive branch of the inner square root. The dispersion relation (102) serves as the model for the shear-horizontally polarized wave propagation in a periodic grating, see Fig. 9. For frequencies far below the threshold AB = ~(ri2-2e2),

(103)

the eigenmode characteristics are similar to surface-acoustic waves. However, with increasing frequency the localization depth of the wave grows (K± decrease) until,

35

902

V. Plessky & J. Koskela

nn

°

0.04

0.02

0

-0.02

N

-0.04

-0.14 -0.12

-0.10 -0.08 -0.06 -0.04 -0.02

0

0.02

-0.06 0.04

2A/Q Fig. 9. Dispersion curves with coinciding edges of the stopband. Solid curves: r/o=0.269, £0=0, and ei=0.139. Dashed curves: J?o=0, £o=0.295, and £x=0.161. Dash-dotted curves: the approximate solution of Eq. (102), with parameters determined to give equivalent stopband edges.

at the threshold A B , the reflected wave becomes entirely delocalized: it is converted into a bulk wave and radiated into the substrate. This results in pronounced attenuation of the incident wave. The frequencies with q = 0 may be identified as the edges of the stopband. The lower stopband edge occurs at frequency A_ = - i ( 7 ? + | £ | ) 2 .

(104)

For |e| < 0.5?7, the upper stopband frequency is A+ = ~(V-\e\)2.

(105)

However, for the values of |e| higher than 0.5??, A + exceeds A B , the onset frequency for bulk-wave scattering. In this case, the upper edge of stopband cannot be identified and the stopband prematurely collapses. The principal difference of this approach with the classic COM is that the spatial structure (localization depth) of the waves is always properly described, and that the eigenmode can be a combination of a surface wave and a bulk wave. The onset of the bulk-wave scattering at high frequencies and the corresponding attenuation are automatically included into the model.

36

Coupling-of-Modes

3.2.2. Abbott-Hashimoto

Analysis

of SAW Devices

903

STW-COM

Abbott and Hashimoto succeeded in combining Plessky's dispersion model with the COM framework.33'37 In their construction, the dispersion relation is characterized by five parameters rather than two as in Plessky's formulation. In this case, the number of independent variables is reduced by finding an analytic equivalence between the parameters in the two models. This section reviews their model. Let R(x) and S(x) denote the slowly-varying amplitudes from Eq. (42), and assume modified COM equations of the form '

dR{x) — —i5sTwR(x) + iKRS(x) + iaV, dx dS(x) = -insR(x) + i5STwS(x) - ia*V, dx dl(x) = +2ia*R(x) + 2iaS{x) - iwCV. dx

(106)

Here, the modified detuning parameter is < W

- A-AV

+ \KB\ I / ( A ) ,

(107)

and t h e reflectivities KR and Ks are f KR=K+KSU{A) \ Kg = K* + K^u(A),

( K

'

and A is the frequency detuning from Eq. (98). The terms proportional t o t h e function z^(A) originate from the requirement of energy conservation in a system with four modes, two of which are surface waves, two bulk waves. The function encompasses the attenuation and strong frequency dispersion resulting from the backscattering of the surface modes into the counterpropagating shear bulk modes, and it is of the form v{A) =

\ . (109) V A B - A + 7/B In the absence of losses, KR and KS are complex conjugates. However, at frequencies where the surface wave scatters into the counterpropagating bulk wave, the relationship is broken. The STW-COM equations (106) yield dispersion relation q(A) = ± y (<5 S T w(A)) 2 - K R ( A ) K S ( A )

(110)

The quantities A y , A B , K, KB, and T?B are the parameters of the theory. Abbott and Hashimoto further proceeded t o derive a direct equivalence between the dispersion relations (102) and (110), allowing the five parameters t o be evaluated from those of Plessky's model; they also gave empiric formulas for r\ and e, determined from numerical simulations, as functions of the metallization ratio and the relative thickness of the aluminum electrodes.

37

904

V. Plessky & J. Koskela

The physical interpretation of the parameters is very illustrative from the point of understanding the dispersion characteristics. As discussed above, A B marks the threshold frequency for STW scattering into bulk waves. The parameter

v2 *v = - \

(111)

describes the position of the center of the stopband at the limit of vanishing interaction between the counterpropagating waves, e -> 0. The interaction consists of the coupling between surface waves, described through the parameter

« =±H^±Me«-,

(112)

and the influence of the bulk wave, present through t h e parameter

and the function v(A). The remaining parameter r\B = 77 + \e\ / 2 describes the effect of the boundary condition on the SSBW propagation. 3.2.3. Remaining

problems

The construction of Abbott and Hashimoto is brilliant in that the COM formalism, providing closed-form formulas for the components of the P-matrix may be used and simultaneously, the S T W dispersion characteristics are properly described. However, a few problems still remain unresolved. Although the approximate 6 closed-form dispersion relation (102) is convenient and illustrative, it results in slightly incorrect asymptotic behaviour far from the stopband, see Fig. 9. This discrepancy is due to treating the unperturbed wave as a surface-skimming bulk wave (SSBW). This approximation is good only if the uniform load, described by parameter n, is small. At and near the stopband the localization depth is determined by the Bragg reflections, but for large detunings even a small uniform load is important and the wave behaves more like a Love wave, weakly localized near the surface, rather than like a SSBW. T h a t gives a relatively small but systematic error in velocity. This difference has also been observed based on numerical computations, and a correction constant c ~ 1 t o be included into the dispersion relation has been suggested 37 : q(A) = ±c^/(5STw(A)f

- KR(A)KS(A).

(114)

Although the model takes into account the scattering of the surface waves into bulk waves, the agreement of the excitation characteristic of the surface waves is ' T h e exact solutions to the dispersion equation (97) may also be found. With some algebra, solving the equation may be converted into the task of finding the roots of a quartic polynomial. Since these may be solved exactly, the dispersion relation is available in closed form. However, because of the length of the resulting expression, the approach is practical in numerical evaluation only.

38

Coupling-of-Modes Analysis of SAW Devices 905 not satisfactory. Due to changes in the localization of the two components of the STW eigenmodes, the interpretation of the wave amplitude as normalized to the power flow, Eq. (37), is difficult, and the transduction parameter a tends t o vary with frequency. 37 ' 34 ' 80 The excitation of bulk-acoustic waves is not covered at all. In synchronous resonators, bulk-wave radiation is the dominant loss mechanism at frequencies close to and above the threshold frequency vB/2p. Furthermore, although the theory describes the SAW-BAW conversion in a periodic grating, the additional conversion occurring at discontinuities, such as gaps 8 1 and the edges of the structure, is not taken into account. The difficulty is especially severe for STWs since the structure of the wave can be completely different inside the electrode grating and on the free surface—sometimes a STW does not even exist on a free surface. Numerical methods based on the integral equation approach have been proposed for modeling these effects, 82,83 but these are computationally more intensive than the COM theory. Until very recently, the waveguiding properties of LSAWs have received little attention and, from the point of device modeling, they form a major unsolved problem. The surface wave slownesses in strongly coupled piezoelectric cuts, such as rotated Y-cut LiNb03 and LiTaOs, are highly anisotropic, leading to complicated physical behaviour and making simple waveguide models, based for example on a paraxial approximation, unreliable. 4. E x t r a c t i o n of C O M P a r a m e t e r s The coupling-of-modes model is phenomenological and depends crucially on the explicit COM parameters which must be known to high accuracy. The parameters may be achieved in various ways: directly, for example, by laser probe techniques, indirectly by fitting the COM model t o electric measurements from devices or test structures, or theoretically from analytic perturbation theories or more rigorous numerical simulations. Among these, the electric measurements from specially designed test structures seem by far the most reliable method—it is precisely the electric response which is usually of the main interest in SAW devices. Unfortunately, experimental parameter extraction is both expensive and time-consuming, since the parameters have to be individually determined for each substrate with every material, size, shape, and structure of the electrodes. Moreover, uncertainties in the properties and the geometry of the electrodes due to the manufacturing technology limit the accuracy of the results obtained. For this reason, numerical methods based on the finite-element method and/or rigorous Green's function techniques have recently been developed. 4 . 1 . Parameter

extraction

from

test structure

measurements

The extraction of the COM parameters from measured data 8 4 ' 2 9 ' 3 0 - 8 5 ' 3 1 ' 3 4 ' 6 8 is widely practiced because it provides a working set of COM parameters for a given technology, even if all the fine details of the electrode structure (e.g. the shape of

39

906

V. Plessky & J, Koskela

Fig. 10. Test structure for COM parameter extraction.

the fingers) are not known. The problem of exact measurement of SAW parameters in periodic electrode structures is not new - it has existed as long as SAW devices have been designed. The pioneering work was done by C. S. Hartmann 8 4 who proposed a multi-transducer test structure and original methods to determine SAW propagation parameters from the electrical measurements of scattering parameters. The fast Fourier transform (FFT), analysis of pulse propagation in the time domain, and time gating were applied. These methods also include measurements of transmission characteristics. For leaky surface-acoustic waves it turned out that the signals coming to the output transducer were often too complicated, involving a mixture of SAW, LSAW, and bulk waves. However, a synchronous uniform oneport resonator, depicted in Fig. 10, proved capable of serving as an excellent test structure. 2 9 ' 3 0 It allows practically all important parameters to be extracted from a single admittance measurement. An example of the admittance of a one-port LSAW resonator is illustrated in Fig. 11. The response is very clean and displays a few features directly related to the values of COM parameters. It is dominated by the resonance peak occurring at one edge of the stopband, while a much weaker resonance takes place at the other edge, as discussed in Section 2.2.5. Immediately above the resonance the susceptance (imaginary part) is negative, but it then increases and crosses the zero at the antiresonance frequency. As the frequency approaches the bulk-wave threshold, a pronounced attenuation appears due to the scattering of the LSAW into BAWs, and the conductance (real part) increases because of synchronous BAW excitation. Extraction of the COM parameters from the admittance may be done in several ways, but basically the edges of the stopband yield the velocity and the reflectivity. The small oscillations in the conductance, visible in the expanded view, Fig. 11(6), may be used to determine possible additional dispersion of the velocity. The values of the transduction parameter and capacitance are reflected in the strength of the resonance and the level of susceptance far from the stopband, respectively, and they together determine the resonance-antiresonance separation. Numerical determination of these quantities based on fitting the computed admittance to the measurement is straightforward. Accurate determination of the attenuation parameter 7 P remains as an unsolved

40

Coupling-of-Modes

Analysis

907

-

0.2

p = 2.2 nm

(«)

JV, = Ng = W = a//? =

0.15 S

of SAW Devices

0-1

i

CD O

149 30 8A.0 0.7

y /1

£ 0.05 CO V

V

E

< ° -0.05 850

850

900

V / [MHz]

900

950

950

1000

1000

/ [MHz] Fig. 11. (a) Admittances of a test structure on 42°YX-cut LiTaC>3 with aluminum electrodes of thickness /i/Ao=4%, and (6) expanded view. Solid and dashed curve: measured real and imaginary part, respectively. Dash-dotted curves: modified COM model. 68

problem. Attenuation decreases the quality factor of the resonance and widens the smaller oscillations in the conductance. However, the extracted value of the attenuation parameter depends strongly on the details of the fitting procedure. As discussed in previous Sections, the COM model is not completely adequate for LSAWs, and the attenuation depends on frequency. A further difficulty is t h a t certain COM parameters tend to result in similar effects. In particular, resistivity also decreases the quality factor. In general, the determination of the COM parameters for LSAW devices usually requires a trade-off between various characteristics of the admittance curve.

41

908

V. Plessky & J. Koskela

An example of the results obtained with the fitting technique are shown in Fig. 11. The patch corrections for leaky waves discussed in Section 3.1 were included in the model 6 8 to improve the agreement on the dispersion characteristics, BAW radiation, and the level of the stopband conductance. The values v=4058.4 m/s, K P = - 1 9 . 6 % , a n = 8 9 - l ( T 5 Q " 1 / 2 , a n d Cn=76-10~5 pF//tm/period were found for the COM parameters of the test structure in this case. 4.2. Parameter

extraction

from

simulations

Although the COM model may be applied for nonhomogeneous structures, it is foremost a theory for counterpropagating waves weakly perturbed and coupled by a periodic grating. On this basis, the ideal structure for the determination of the COM parameters would appear to be an infinite periodic array of electrodes. From the point of a view of numerical simulations, such a periodic structure has one very significant additional advantage over finite structures: only one period of the array needs be modeled, leading to a drastic decrease in the required computational load. Unfortunately, the rigorous simulation of a waveguide is an intimidating task even for periodic structures. Further simplification is usually gained by considering the aperture as infinite, thus reducing the number of the effective dimensions by one. 4.2.1. Simulation

approach: periodic

structures

The simulation of a periodic array involves solving the system of coupled partial differential equations governing the mechanical and electric fields, in a geometry consisting of the semi-infinite piezoelectric crystal and the periodic electrode array. For most purposes it suffices to consider a period consisting of a single electrode. However, more complicated unit periods may be required, for example, in the analysis of single-phase unidirectional transducer cells. The technical details are beyond the scope of this article. There exists an immense amount of literature on the subject and it is impossible to give a comprehensive list of references; we merely attempt t o demonstrate the most prevalent methods currently in use. The fields in the substrate may be modeled with the finite-element method 2 ' 3 (FEM), space harmonics expansion, 4 Green's function techniques using the boundary-element method 5 ' 6 - 7 ' 8 , 9 ' 1 0 - 1 1 - 1 3 (BEM), or both FEM and space harmonics expansion. 14 Due to the high relative electrode thicknesses used in modern R F SAW filters, the Datta-Hunsinger type of boundary conditions are not accurate enough to describe the stresses in the electrode-substrate interface, so the stress distribution must be computed with more precise methods. The most popular approach is probably FEM 2 ' 3 ' 5 ' 6 ' 7 ' 8 , 9 ' 1 0 ' 1 3 ' 1 4 although, both the application of space harmonic expansion 4 and the normal-mode expansion 11 have been reported. A FEM/BEM-based simulator capable of treating multi-electrode unit periods has been developed and generously made available to all SAW researchers by Prof. Ken-ya Hashimoto. 8 6 Conceptually, the methods for the analysis of periodic structures may be clas-

42

Coupling-of-Modes

Analysis

of SAW Devices

909

sified into two principal categories. In the eigenmode analysis, waves propagating freely on electrically open and shorted structures are considered. The phase shift, i.e., wavenumber, in the elastic and electric fields between the successive periods is to be found as a function of frequency; as a result, the dispersion curves are obtained. A limitation of this method is that the coupling to an applied voltage can be analyzed only indirectly. Furthermore, complex-valued wavenumbers have to be considered, which is somewhat problematic in the Green's function methods and requires additional assumptions on the continuation of the Green's function into the complex plane. 8 7 ' 8 8 Alternatively to the eigenmodes, the generation problem may be analyzed: the system is modeled driven by a voltage source and the interest is in the currents on the electrodes. Since the generation problem more resembles practical experiments, the results of the generation problem are easier to interpret that those of the eigenmode analysis. Furthermore, the generation formulation includes a description of the electrically active eigenmodes, since these appear as singularity points in the excitation analysis. 4.2.2. Harmonic

admittance and COM

As an archetype of a periodic electrode structure, consider the infinite electrode array shown in Fig. 12; the treatment is easily generalized for more complicated unit periods. 8 6 ' 8 9 ' 9 0 Driven by a harmonic voltage configuration, such that electrode voltages are of the form Vn(^) = Voe~l2lrrn, the electrode currents In are also of the same harmonic form: J r a ( 7 , / ) = ^o(/) e _ l 2 , r 7 n , Consequently, the function

y(7,/) =

Inh,f)

_Hf)

K(7)

V0

(115)

may be defined. This is nothing else than the strip impedance from the classical work 5 7 ' 5 8 of Bl0tekjaer et al, elegantly analyzed and relabeled as harmonic admittance by Zhang et af1; the latter nomenclature is employed here. Since an arbitrary voltage configuration in a periodic array may be expressed through 7-harmonic voltages using Fourier-transform techniques, the harmonic admittance contains a complete description of the electric response of the structure, see the discussions in Refs. 7, 91. In particular, the zeros and poles of the harmonic admittance respectively indicate the eigenmodes of electrically open and shorted

V0ea"

\e-aicr

y^MKY

.. 1 p-<W

klefoode-l substrate

-EZ za_

V///\

V777^

Fig. 12. Periodic array of electrodes under 7-harmonic drive voltage. The electrode currents In(~f) follow the electrode voltages Vn(l) such that their ratio, the harmonic admittance Y(l)=In(l)/Vn{-y), remains a constant.

43

910

V. Plessky & J. Koskela

gratings. Consequently, the harmonic admittance may be interpreted as the ratio of the dispersion relations for open and shorted gratings:

YM)

(n6)

'WTY

This relation has nonobvious generality and it serves as the connection between the propagation and excitation problems. Rigorous mathematical proof of the theorem was recently found by Biryukov. 92 It has been proven that the functions Doc and Dgc may be obtained as the determinants of appropriately defined systems of equations obtained e.g., from numerical computations with the boundary-element method. The conditions Doc=Q and Z?sc = 0 respectively define the dispersion relations for open and shorted electrode arrays. Equation (116) suggests that the basic requirement for successful parameter extraction is that the COM model should be able to describe accurately enough, the dispersion relations in the structure under consideration. For comparison with the rigorously computed harmonic admittance, an approximate COM-model may be derived 4 9 ' 9 3 for the harmonic admittance for the case 7 ss 0.5: Ycou(qJ)=i«C0Sin{qP)S2--^f-f , qp d* — | K | ' — ql

,«0.

(117)

Here, Co in the capacitance per period, and q denotes the deviation of the wavenumber of the electrode voltages from a single-electrode transducer, q = (5(7—0.5). Note that the numerator and denominator in the r.h.s. of Eq. (117) indeed are the COM dispersion equations for open and shorted gratings, respectively, as expected. If the COM theory is accurate enough, the velocity, coupling coefficient, and transduction coefficient may be easily extracted from the rigorously computed capacitance and the edges of the stopbands for shorted and open gratings. 2 5 Careful analysis 94 of the COM equations shows that in a symmetric structure the stopbands for open and shorted gratings feature one coinciding edge, whereas in a unidirectional structure the stopband edges are separated from each other, see Fig. 13. Let / s c ± denote the edges of the stopband for shorted grating. Then, the velocity and the magnitude of the coupling coefficient may be found by inverting Eq. (56): f

V

= P (fsc+ +

fsc-)

./«+ - /-cI K I 2p = 27T

(118)

JSC+ + /s<

Subsequently, the magnitude of the transduction coefficient may be extracted from the difference between the centers of the stopbands, and the width of the opengrating stopband yields the degree of the unidirectionality # u n ; = 0T—26e. Attenuation is to be determined either based on the dispersion curves with fitting techniques, or from the halfwidths of the resonance peaks. 4 9 The COM theory and Eq. (117) usually apply well for Rayleigh-type surfaceacoustic waves close to the stopband. As an example, the COM parameters were

44

Coupling-of-Modes

Analysis

of SAW Devices

(b)

(a)

SC

SC

oc

(/)

/

Q

<$

/,

s

k // \\

f /

/

v.

f /

K

y

/^SC

"" •» ^

A

- - '

911

oc

8

/\

*«-,

I

/

« ^

/

SC

\

<( L( / ks /' - - '

f

/,

pp

N

/y

/

/

OC

/

oc

/

f /

(c) SC \

/ J

c

//V ^ 5?

/ SC /

// /

J

i

^

OC

/

/y

/f

-'ar

x "V

/

\

/

/ /

(d)

-

S

/„

s

j

1

7 • "•

SC

/

/ ^

\ / \

•i,

/ SC

—

/

OC

/

f •'arl A

/

/

'_.'/«2

N

/

**• ^

oc

/ '

/

/

Fig. 13. Dispersion curves 94 for shorted-grating (sc) and open-grating (oc) eigenmodes with (a) a %/{^favCp) < KP, (b) 0 < KP < (^/(irfasCp), and (c) K P < 0, in a bidirectional structure, and (
determined for SAW on 128°YX-cut LiNbOs substrates with rectangular aluminum electrodes. Applying the procedure described in Ref. 49, the results shown in Fig. 14 were obtained. However, difficulties are often encountered with LSAWs, since these often feature additional dispersion and strong frequency-dependence of the attenuation and the strength of the electromechanical coupling. The stronger the discrepancies between the COM model and the rigorous simulation, the harder it is to find an optimal set of parameters: a trade-off between different features of the wave must be made. For surface transverse waves and Bleustein-Gulyaev waves, and for LSAWs close to the bulk-wave threshold, COM theory and Eq. (117) fail as discussed in Section 3.2. In this case, the analytic model 9 5 (v/2(+g-A)-r?oc) *STW(9,/) =

^2(-q-A)-Voc)-\e (119)

iuC0(q)

(V2(+9-A)-r?)

^2(-q-A)-r,)-\ef

consistent with the dispersion equation (101), may be used. Here, the effective capacitance per unit period Co(q) varies slowly with q, and r]oc and e o c are weakly frequency-dependent dispersion parameters for an open grating.

45

912

V. Plessky & J. Koskela

2 . 0 1 1 ' ' " • I . ' : • l '• • • • t

0.3

0.4

0.5

•

'.

.

-- i — ^ J

0.6

0.7

:

'->

2.0 L^

0.8

0.3

:

^-—i—-^—I—:

0.4

. -

0.5

0.6

:

I

•

, ; -

0.7

I—_J

0.8

alp alp Fig. 14. Contour plots of (a) Velocity, (b) reflectivity, (c) transduction coefficient, and (d) capacitance, for SAW on 128°YX-cut LiNbC-3 substrates, with rectangular aluminum electrodes.

Unfortunately, if the model (119) is directly used to determine the transduction coefficient a in the STW model of Abbott and Hashimoto, difficulties appear above the frequency A B - The discrepancy arises from the generation of bulk waves, included in Eq. (119) but ignored in STW-COM. An accurate description for the excitation of shear horizontal waves within COM theory remains as an unsolved problem. 4.2.3. Accuracy of theoretical

simulations

Rigorous theoretical methods have their pros and cons. In principle, they are very accurate although slow. In practice, they suffer from uncertainties in electrode shape, material parameters, wafer quality, and wafer homogeneity. The more precisely the physical parameters of the system (geometry, elastic and piezoelectric material constants) are known, the more reliable are the simulations. However, velocity shifts due to waveguiding effects and other 3D effects are not modeled, and this can occasionally be a problem. Due to the waveguiding effects and the long range of the electromagnetic interactions, the parameters actually depend on the aperture and on the length of the structure; this especially applies to the capacitance. In short devices the electric and elastic fields may strongly differ from those in an infinite device.

46

Coupling-of-Modes

Analysis

of SAW Devices

913

For these reasons, theoretically determined parameters are, at the moment, not accurate enough for all purposes. For the level of precision required in device design, the COM parameters need to be determined experimentally as functions of the aperture and the device length. However, because the theoretical approaches allow the parameters to be studied rather arbitrarily as functions of temperature, crystal cut, electrode dimensions etc., the simulators are most useful for analyzing sensitivity of designs to technological variations, and for comparing different substrates, crystal cuts, and electrode structures. 5. D e v i c e M o d e l i n g a n d D e s i g n The purpose of this paper is to show how the COM model can be applied t o SAW device analysis. We will not go into details of SAW device design as such (a topic so vast that a few more books should be written to cover it.) Also, we will not discuss in detail the advantages and disadvantages of concrete design approaches. Currently, the main classes of SAW devices are • transversal filters—featuring relatively high loss but very precisely controlled amplitude and phase characteristics. The COM model is practically never used for the design or analysis of these devices. • low or medium loss intermediate frequency (IF) filters for mobile communication systems and other applications. The suitability of the COM model is excellent. • SAW resonators. The COM model is often used. • radio ment SAW COM

frequency (RF) filters of different types: ladder/lattice impedance elefilters (IEF's), coupled resonator filters (CRF's) such as double-mode filters (DMS's) and resonator filters, multi-transducer filters (IIDT's). model may used as well as the other methods.

• reflective array compressors (RAC's)—different models, including COM, are used in design and analysis. • others, such as SAW sensors, actuators, and tags. The choice of the model is dictated by the nature of the physical phenomena relevant for device performance. The COM model usually gives advantages if multiple reflections are strong and essential for the device operation, if low losses are of importance and the absolute value of losses must be estimated very accurately, or if the device structure can be subdivided into homogeneous periodic regions. Currently, the design and analysis of low-loss filters for mobile phones is the area where the COM model is most widely employed. In device analysis the layout and the electrical response of the device are known, and the details of surface wave behaviour are to be characterized. A typical example 0 c

Another example is "inverse engineering".

47

914

V. Plessky & J. Koskela

of an analysis problem is the extraction of the COM parameters from test structure measurements. On the other hand, in device design the COM parameters are reasonably well known, while the optimal device geometry is to be determined. COM is well suited for both purposes, since it allows fast simulation of the device response, enabling optimization of either the COM parameters (analysis) or the device geometry (design). 5 . 1 . SAW

building

blocks

In the design of SAW resonators and low-loss filters, rather complicated structures, including sometimes many dozens of elements are used. However, the elements are usually chosen from a few basic SAW building blocks, the most important of which are • interdigital transducer • reflector • gap (open or metallized) between the other elements. Much more rarely used components include • multistrip coupler • reversing multistrip coupler. We will not continue the list of other SAW components, such as waveguides, unidirectional transducers, beam compressors, fan transducers, oblique reflectors, and non-linear elements. However, our estimates of the relative importance of the described components for design are to be taken with reservations. Firstly, our interests focus on low-loss filter applications. Secondly, components that are not important today may be of primary importance tomorrow. 5.1.1. Interdigital

transducer

The formulas in Section 2.2.5 completely describe the properties of an interdigital transducer with internal reflections. The electrical features of some IDTs are illustrated in Fig. 15. One can see that strong reflections have a crucial influence on the admittance even for a relatively short transducer. The response of the IDT with strong reflections resembles more t h a t of a classic LC-resonator t h a n the sineresponse characteristic to reflectionless IDTs. Due to the reflections, the maximum of the admittance is shifted to lower frequency, and at the resonance the magnitude of the admittance is almost three times higher than that for a reflectionless device. In a low-loss device design, the strong reflections from the electrodes are used to increase the interaction of the waves with electrodes and to develop resonance-type behavior in relatively short structures. This allow the devices to be smaller, and many design ideas have been developed based on the concept. Although the COM model is not perfect for leaky waves (and, especially, for STW), the discrepancies

48

Coupling-of-Modes

-0.02 700

750

800

850

900

950

Analysis

1000

of SAW Devices

1050

915

1100

/ [MHz] Fig. 15. Simulated IDT with Nt = 31 electrodes, with and without the reflectivity KP = —21.5% and attenuation fp = 3.6 • 1 0 - 3 Neper/wavelength. The parameters are typical for 42°YX-cut LiTaC>3 substrate.

are located at high frequencies, where bulk waves are involved. Fortunately, this region is often located outside the filter passband, and the increased losses improve the suppression levels. Internal details of the electrode structure are not directly manifested in the COM model, only the values of the COM parameter are changed. From the electric network point-of-view, the IDT is just a black box with a frequency-dependent impedance, which for long transducers closely resembles that of a LC resonator or a quartz crystal resonator. Depending on the application, the transducer can be matched (or mismatched) to achieve desired performances. We will touch these questions below. 5.1.2.

Reflectors

SAW reflectors are characterized by the reflection coefficient R = Pu. A typical response for LSAWs in illustrated in Fig. 16. The periodicity of the ripples in the reflection coefficient outside the stopband is inversely proportional to the number of fingers, A / / / 0 = 1/Ng (about 15 MHz in the example in Fig. 16). Note that the frequency-dependences of the reflection and transmission coefficients are not symmetric. Below the stopband the reflectivity is high and the ripples are pronounced, while above the stopband the attenuation is strong due to the LSAW being scattered into BAW's, and the ripples appear as smoothed. The reflection coefficient of the Bragg reflector can be measured directly, but a

49

916

V. Plessky & J. Koskela

800

820 840 860 880

900 920 940 960 980 1000

/[MHZ] Fig. 16. Simulated LSAW reflector on 42 c YX-cut LiTaC>3 with Ng = 60 electrodes and KP = -21.5%.

rather sophisticated technique must be applied. One elegant method was used by P. Wright. 9 6 The characteristics of a SAW Bragg reflector include • in the stopband the reflectivity is close to unity if \K\L^$>1. The relative stopband width depends only on the normalized reflection coefficient, being equal t o A / / / 0 =

\KP\/IT.

• at the center of the stopband \R\ = tanh(|K|L),

\T\ = 1/COS1I(|K|L)

(120)

for \K,L\=3, \R\ « 99.5%, while \T\ « 0.1. Attenuation decreases the reflectivity even for a very long reflector. • at the edges of the stopband, where the eigenmode wavenumber equals the half structure wavenumber Q/2 (q = 0), the reflection coefficient is still rather high and the wave amplitude decays along the grating, but not exponentially. • the close-in sidelobes of the transmission curve for a uniform grating can be only a few dB lower than t h e reflectivity in t h e center of the stopband. This can be a problem in some applications. The position of the n t h zero depends on the grating length and it is given by the formula

• energy losses in the form of bulk wave scattering occur when an incident SAW enters the reflector from a free crystal surface. These losses are comparable with the bulk wave scattering from one electrode. 59 They are not negligible in high-Q resonators on quartz or in low-loss filters on substrates with strong piezoelectric coupling.

50

Coupling-of-Modes

Analysis of SAW Devices

917

|K(*)| l

(a)

0.20 0.10 0

L/2

L/4

3L/4

X

(b)

L3 Fig. 17. (a) desired reflectivity and (fc) physical realization.

Weighted reflectors The ripples (sidelobes) of the reflection coefficient of a uniform reflecting grating can be unacceptably high when the frequency response of the reflector is used to form the filter characteristics (and also in some other cases). The ripples can be significantly suppressed by weighting the reflectivity, that is: by varying the reflection coefficient K(X) along the grating. As an example of a weighted reflector, consider the simple technique proposed by S. Kondratiev. 9 7 Assume that a reflector with the spatially varying reflectivity shown in Fig. 17 is designed; the reflectivity in the center of the grating is twice as high as in the ends. To realize such a reflector, either amplitude or (better!) aperture may be weighted. One can actually treat such a reflector as a combination of two reflectors, each 3L/4 long, put together with an offset of L/4. The total reflection coefficient of such a reflector can be calculated as Rtot = RZL/AO- + e i2fcL / 4 ) oc sin(*3L/4)cos(JfeL/4)

(122)

One can see that the first sidelobe of the reflection coefficient for one 3L/4-grating, roughly determined by the condition sin(A;3I//4) = 1, is eliminated by the first zero of the second factor, determined by cos(kL/4) = 0 (for arbitrary, but great length L). The other close-in sidelobes are also significantly suppressed. The same result is obtained by more rigorous analysis, obtained by connecting P-matrixes of 3 reflectors. The gratings are assumed to be uniform, with reflectivites KP = - 1 0 % , KP — —20%, and KP = —10%, respectively. The results are shown in Fig. 18.

51

918

V. Plessky & J. Koskela

900 / [MHz] Fig. 18. Weighted and uniform reflection coefficient from a grating with iVg = 80 electrodes and K»=-20%.

The general treatment of a spatially varying reflectivity K[X) requires numerical methods. For simplicity, assume that t h e substrate is bidirectional. Then, without loss of generality, K(X) can be taken as real-valued. It proves convenient to define a quantity S{x) r(x) = (123)

R(x)'

Evidently, for the boundary condition r(L) = 0, the function r(x) describes the penetration of the acoustic field into the grating and, in particular, the value r(0) equals the reflection coefficient P\\—P22 of the grating. 5 9 Using the COM equations, Eq. (44), one may show that — = -IK(X)

ax

( l + r(x)2)

+

2iSr(x).

(124)

This first-order nonlinear differential equation belongs t o the class of the Riccati equations. 9 8 A solution in closed form may found in special cases, such as the uniform structure considered in Section 2.2, but one does not exist in the general case. However, at the center frequency of the grating, / = v/(2p), the detuning 5 vanishes, and in this case r(x) = i t a n h

/

K{X')AX' J .

(125)

In particular, -Pn(/o)=r-(0) = itanh

52

/

Jo

K(X')AX'

(126)

Coupling-of-Modes Analysis of SAW Devices 919 Here, the accumulated reflectivity f0 n{x')dx' is the reflection coefficient of the grating at the central frequency without accounting for the multiple reflections. 59 The result shows that to obtain large total reflectivity, the mean value of the reflectivity should be large. In practice, the realization of reflector weighting is not trivial and weighting is seldom resorted to. A few tricks can potentionally be used: changes in the geometry of electrodes, or in aperture—in any factor influencing the phases or magnitude of the reflectivity of the fingers. At high frequencies, however, many such possibilities are restricted by the precision of the manufacturing technology. Changes in the electrode structure can result in changes in the SAW velocity and the phases of reflected waves. Consequently, fine corrections are needed in the position of the reflectors, making the design process rather complicated. However, using weighted reflectors as a part of SPUDT 6 3 ' 6 4 ' 6 2 allowed the invention of the resonating SPUDT filters with excellent performance. 5.1.3. Gaps Gaps are used t o change the phase of the wave between transducers and reflectors. In materials with weak piezoelectric coupling, such as quartz, the phase change results simply from wave propagation. However, in strongly coupled substrates the effect of gaps is more complicated. The phase change is difficult to predict based on phenomenological models, and losses occur due to scattering of the surface wave into bulk waves at the discontinuity of periodicity. Consequently, the following P-matrix is introduced for gaps:

p •'gap

0 (l-7gaP)e-i"d/'Ugap 0

(l-7gaP)e-iwd/^p 0 0

0 0 0

(127)

Here, d denotes the width of the gap, 7 g a p is the loss parameter, and v g a p describes the SAW velocity in the gap. Quantities 7 g a p and w gap must be treated as phenomenological parameters t o be determined from analysis of experimental data or rigorous simulations. 81 Possible reflections from the gap are ignored. 5.1.4. Multistrip

couplers

Multistrip couplers" (MSCs) are used to transfer the SAW propagating in one acoustic channel into another. In the simplest case, shown in Fig. 19(a), the element consists of a periodic system of open electrodes with a pitch smaller than half wavelength of the surface wave of interest, overlapping both channels; in-between the channels the pitch can be modified to decrease losses. SAW propagation in the first channel generates electric potentials, which are transferred by the electrodes and generate a wave in the second channel. Contrary to a Bragg grating, which couples counterpropagating waves, in a MSC the interaction occurs between parallel-propagating modes. The coupling results in sin/cos-type of energy transfer from one channel t o the another and vice versa, see Refs. 46,100.

53

920

V. Plessky & J. Koskela

Track 1

Track 2

J^^Vtmskl

d%fr

4 ^ s; Track 2

(a)

(b)

Fig. 19. Schematical (a) MSC and (6) RMSC.

The multistrip coupler can be accurately modeled by COM. 1 0 1 The model results in a 4 x 4 P-matrix, which describes the coupling of the waves in the two channels. The characteristic length for energy transfer from one channel into another is inversely proportional to the piezoelectric coupling coefficient. 46 ' 100 For quartz too many electrodes are required and MSCs are rarely used. 1 0 2 The MSC has quite wide frequency band, although attempts to use it as a frequency-selective element have been proposed. 1 0 3 If a MSC of more complicated form, such as U-shaped or J-shaped is used, the coupled acoustic channels do not need to be parallel. Onedirectional transducer operation can be achieved by combining an IDT with such MSCs. 4 6 In the early days of SAW devices, the idea of transferring the wave into another channel was employed in many innovative designs. The main advantages were • suppression of bulk waves propagation from the input IDT to the output IDT (used in SAW TV filters) • decrease in device area due to more optimized use of all possible directions of propagation • compensation - using different propagation directions to compensate for undesirable second-order effects. Currently, MSCs are used rarely, 1 0 4 ' 1 0 5 especially in low-loss filters. There are a few disadvantages which prevent the wide use of MSC: • since the coupling occurs between waves propagating in the same direction, using a MSC does not help much t o decrease the device size • in coupled-mode resonator filters (see below) the aperture is relatively large and, at high frequencies, the resistivity of the electrodes of the MSC gives nonnegligible losses • the required small pitch is an additional challenge to fabrication technology

54

Coupling-of-Modes Analysis of SAW Devices 921 • for LSAW filters, with relatively high electrode thicknesses up t o 8% or 10% in h/Xo, using a grating with essentially different pitch gives additional losses due to BAW scattering at the transition regions. Despite this criticism, we believe that using MSCs in resonator filters can be very beneficial in some cases. In contrast to IDTs, the intertrack coupling by MSC may be one-directional. 5.1.5. Reversing multistrip

couplers

The reversing (reflecting) multistrip coupler 1 0 3 ' 1 0 6 ' 1 0 7 (RMSC) combines features of a MSC and a Bragg reflector. It transfers the wave into another channel, simultaneously turning the propagating direction into the opposite. The idea of the component is to connect the electrodes in the first channel to the electrodes in the second channel such that the wave potential in the second channel looks as if it is propagating in the opposite direction, see Fig. 19(6). Danicki also proposed more complicated components, 1 0 7 including grooved reflectors in combination with electrodes. The RMSC features stopband behavior and it has a relatively narrow frequency band of efficient operation, which depends exclusively on the strength of the piezoelectric coupling of the substrate. This restricts the flexibility of design, although very successful applications were recently demonstrated. 1 0 4 ' 1 0 5 ' 1 0 8 The component can be described by the COM model, although it is uncertain to the authors whether this has been done. 5.2. One-port

SAW

resonators

A vast variety of SAW devices may be constructed from the building blocks described above. To model the devices, the building blocks are described through their respective P-matrices, which are then cascaded to obtain the total device response. We will give here three examples of devices, concentrating on the device description by means of COM model: synchronous uniform resonators, synchronous 'hiccup' resonators, and primitive SAW-tags. The last example serves to illustrate the possibility to combine the COM model with F F T analysis in the time domain. There are a few excellent review papers dedicated to resonator design. 1 0 9 ' 1 1 0 We follow the classification given by P. Wright. 1 0 9 5.2.1. Synchronous

uniform

resonators

Synchronous resonators consist of a transducer surrounded by two reflectors which mechanically form a continuation of the electrode structure in the IDT. In the simplest case the transducer is uniform and periodic, see Figs. 2 and 10; we denote such a device as a synchronous uniform resonator. As discussed above, synchronous uniform resonators are widely used as test structures in COM parameter extraction. The component is also commonly used as a building block for impedance element filters (IEFs), such as ladder (lattice) filters, balanced-bridge filters, and notch filters.

55

922

V. Plessky & J. Koskela

Assume that the structure is bidirectional and describe the IDT through the P-matrix P. Let R = Pfx = Pf2 denote the reflection coefficient of the reflectors. Then, from the formula for the admittance of a reflector-transducer-reflector structure, Eq. (55), we findd

y

-*-i-mffifl,)-

(129

>

We have already mentioned a few times synchronous uniform resonators in the context of COM parameters extraction. Now we will add a few more comments concerning the performances of the component as a building block for impedance element filters. Although the above formulas look simple, the analytic derivation of the admittance properties is rather cumbersome. The following statements result from numerical simulations obtained using COM formulas. • If a large frequency bandwidth is desired and the finger reflectivity is high, the optimal geometry of a synchronous resonator for IEF applications is a long, waveguiding transducer accompanied by relatively short reflectors. The piezoelectric coupling is maximal since the wave amplitudes are practically uniform and their magnitude inside the transducer is high, i. e. the transducer covers practically all the area where acoustic field is available and has high intensity. This results in the largest possible distance between the resonance and antiresonance frequencies. The admittance is proportional to the area of transducer. • Long and narrow transducer has low Ohmic losses proportional to the aperture squared (W/X)2. • The first term in Eq. (129) corresponds to the admittance of the transducer. For a long transducer the admittance, given by Eq. (69), is in practice dominated by the driven contribution, Eq. (74). The driven term is proportional to the length of the IDT, whereas the other term in P33 (73) contains the corrections due to the non-uniformity of the acoustic fields near the ends of the long structure. The admittance is very similar to that of a crystal BAW resonator.

• The second term in Eq. (129) describes the admittance variations due to mul-

tiple reflections of the waves from the gratings. The reflectors are necessary: they prevent energy losses through the edges of the structure, and thus improve the Q-factor of the resonance occuring at the low-frequency edge of the

d

Note that as such this formula may be applied to arbitrary symmetric resonators which include a transducer and two identical reflectors. These don't need to be synchronous: the pitch and other characteristics may be different in the IDT and the reflectors, and the presence of identical gaps between the transducer and the reflectors can be easily taken into account via substitution R = (1 - 7 g a p ) 2 e - 2 i ^ / ^ » p P f 1 . Here, d, 7 g a p, and i>gap are the gap parameters discussed above.

56

(128)

Coupling-of-Modes

Analysis

of SAW Devices

923

stopband. As a drawback, the reflectors increase the ripples in the admittance at frequencies below the resonance and close to the high-frequency edge of the stopband. • Finally, the position of the resonance at the low-frequency edge of the stopband makes it more distant from frequencies with pronounced BAW generation. The phase velocity is minimal at the left edge of the stopband, improving the conditions for waveguiding. According to the waveguide theory of Haus 2 1 this difference in velocities is sufficient for waveguiding to occur.

5.2.2. Synchronous

'hiccup'

resonators

The synchronous uniform resonator structure considered above is not very good if maximal Q-factor and small size are required and the resonance-antiresonance distance is of little concern, for example for frequency stabilization in oscillators. In this case the design criteria are cost, frequency tolerance, admittance value at the resonance, and size. 109 Quartz is practically the only material used for this application. The disadvantages of the absolute synchronous resonator are all related to the fact that the resonance occurs at the low-frequency edge of the stopband: • The reflectivity of reflectors at this point is not maximal. This either leads to additional losses or longer gratings. • The device may be too sensitive to variations in the thickness and width of the aluminum electrodes, present because of the limited precision of manufacturing technology. The position of the resonance at the edge of the stopband makes it sensitive to changes in both velocity and reflectivity. To correct these problems, the synchronous 'hiccup' resonator was proposed, see Fig. 20 and Ref. 109. In the center of the transducer there is a gap, which breaks the periodicity and increases the center-to-center distance between the center electrodes by A/4. The center electrodes have the same polarity. Under these conditions the resonance occurs at the center of the stopband, as one can easily demonstrate by considering the phase change of the wave circulating between the two parts of the transducer. Such resonators may without any difficulty be modeled based on COM formulas. One can first connect in parallel two parts of transducer with the gap between them, and then use equation (55) to add the reflectorsf The advantage of having the resonance at the center of the stopband is t h a t the resonance is then insensitive to the finger reflectivity, increasing the yield in the mass production of the device. 109 The price paid is that the electromechanical coupling e

We leave this as an exercise to the reader, as well as the demonstration of the fact that the 'hiccup' resonator always has only one pronounced resonance.

57

924

V. Plessky & J. Koskela

P~l

.-•j p/Kn+j)

Fig. 20. Synchronous one-port hiccup resonator.

0.15

p =4|im

ReY(/)

o.n

a/p= 0.5 „

0.05 \

ImY(/)

v

a

i . - -?%^u .—-j -0.05 V

-0.1 460 480 500 520 540

_J

i—

560 580 600 620 640 660

/ [MHz] Fig. 21. Admittance of a synchronous hiccup resonator on 64°YX-LiNbC>3.

of the resonance to the transducer is reduced: the SAW amplitudes decay exponentially from the center to the ends of the device and the outermost parts of the transducer are not efficiently coupled to the amplitude distribution. Consequently, increasing the number of electrodes increases the magnitude of the admittance at resonance only up to some limit, in contrast to the synchronous uniform resonators where the admittance is roughly proportional to the number of electrodes. Again, for strong piezoelectric materials the situation is not so cloudless. Fig. 21 shows the admittance of a 'hiccup' resonator admittance on a 64°YX-cut LiNbC>3 substrate. In the figure the position of the resonance can be seen to have slightly but visibly shifted from the center of the stopband, indicating that the velocities inside the gap and in the periodic structures are significantly different. Although strongly piezoelectric substrates are rarely employed in resonators, they are used in a few notch filters and voltage controlled oscillators (VCO).

58

Coupling-of-Modes

reflector 1 ',

calibration reflector

WT .

1

Analysis

\

reflector \

\

u

•

**

•

of SAW Devices

925

2

A_

p \

1

'•••

JLg < j^i < L>2

£ s

H

i Li
Fig. 22. Primitive SAW tag, consisting of a transducer and two reflectors. The response from a calibrating reflector may be used to compensate for temperature shifts.

5.2.3. SAW tags SAW tags may also be constructed from a transducer and a few resonators, 1 1 1 see Fig. 22. However, they present a very different class of devices compared to one-port resonators. Connecting an antenna to the transducer, the tag can be interrogated by a short R F pulse (although more complicated systems are often implemented in practice). The pulse received by the antenna launches from the transducer a surfaceacoustic wave which propagates to the reflectors and, being reflected, returns to the transducer and is reradiated by the antenna. Such delayed pulses can be received by an interrogation unit at some distance. The pulses contain information which may be coded into their time delays, phase, or amplitude. The ISM frequency bands are often used for SAW tags; one of them is from 2400 MHz to 2480 MHz. An ideal transducer for SAW tag applications features • low loss in the desired frequency range, self-matched to 50 Q • no mechanical reflections from the transducer • rather large aperture to avoid diffraction. Following the philosophy of this paper, we are not going to describe a real design procedure for SAW-tags, but limit the discussion to the COM modeling of the device characteristics. The admittance of the tag can be calculated using the cascading formulas (49)-(55). For example, the reflectors on each side of the transducer may be cascaded first, and the results may then be cascaded with the IDT P-matrix to obtain the net response of the tag. In the general case there is no need to do this analytically; such tasks are most conveniently performed in numerical form by a computer. However, for illustration purposes assume that we have only one reflector. Then, the cascading formula (54) yields

*33

- ^33

~

1 _ RPIX>T'

^

'

where the reflection coefficient R = R-ie~2ikd includes also the phase shifts due to the distance between the IDT and the reflector. Assume that the reflections from

59

926

V. Plessky & J. Koskela

the transducer are negligible, P^T reduces to ^

a S

= 0, as desired. Then, the response of the tag = ^3DT-2i?(P1I3DT)2.

(131)

Here, the required components of the P-matrix for a reflectionless transducer-^are Pj 3 D T = i a N

p

^

iSL

e~

^/2

(132)

and P33

„ 9»,9/sin2A .sin(2A)-2A\ = 2a2N2 { - g - +i—L-Jg j +

„ ia,Ctot.

(133)

Above, L I D T = Ao./Vp is the length of the transducer, the IDT has Np periods, and A denotes A = TT^NP.

(134)

70

The second term in the r.h.s. of Eq. (131) represents the contributions to the admittance by the reflected waves returning to the transducer. Due to the assumed absence of reflections from the IDT, the response is clear of multiple reflections. Unfortunately, multiple reflected signals nevertheless arise because of the parasitic capacitance of the package and the inductances of the bonding wires. 1 1 2 Simplifying the situation just for illustration purposes, adding only a series inductance L w due to the bonding wires, the net admittance pTag

^33

Y =

T g

(135)

is obtained. Prom the factor in the denominator it may be seen that the response contains all powers of e~2lkd, corresponding to multiple reflections from the transducer. The admittance of a tag including one transducer and two equivalent reflectors, situated at different distances on both sides of the IDT, is illustrated in Fig. 23(a). The effects of parasitic elements were included using a model similar to that described in Ref. 112. Transforming the frequency response into the time domain with the fast Fourier transform algorithm, the impulse response of the tag is obtained. The main reflections, as well as multiple reflections and roundtrip reflections are clearly visible in the time response, displayed in Fig. 23(6), 5.3. Two-port

resonators

and resonator

filters

113

Historically, two-port SAW resonators were developed as quartz devices for narrowband filter applications, 1 1 0 ' 1 1 4 ' 1 1 5 , see also Ref. 116 and the references therein. In these devices two Bragg gratings serve as narrow band mirrors to create a FabryPerot type of resonator. The transducers are placed either outside or inside the •^It is interesting to note that the formulas (132) and (133) are valid for arbitrary long transducers (although attenuation must be accounted for).

60

Coupling-of-Modes

0.005 2100

2200

2300

2400

2500

Analysis of SAW Devices

2600

2700

927

2800

/ [MHz]

N|

e La.uJ

S

V5

res]

o

„ F F 1 .„

UV 0.5

r i ii vu

1.0

J2

1.5

(b)

R2

Rl

(

R2

1 Ii \4 i

iJ V i Ul

2.0

2.5

3.0

time [|xs]

3.5 4.0

\

i\ \t

4.5

5.0

Fig. 23. Simulated tag with an IDT and two reflectors: response in (a) frequency and (6) time domain. Fast oscillations in the frequency-domain response are contributions of the reflected signals. In the time-domain response one can see the desired signals (SI and S2), their reflections (Rl and R2), as well as other parasitic responses such as round-trip signals. "Signals" before 1.0 fis are FFT artifacts and they do not exist in reality.

61

928

V. Plessky & J. Koskela

D-

G

w T2

Tl kipr

•NGPO-

T2

G

A^ft

120

Fig. 24. Coupled resonator filter consisting of a center transducer T l connected to the input, two identical transducers T2 connected to the output, and two identical gratings G.

cavity; in the latter case the positions and the properties of the transducers must be chosen carefully. 110 Single-mode operation is aimed for in most cases, but sometimes two identical modes are coupled to get optimal splitting and to create a narrow rectangular passband with low losses. The modeling of a Fabry-Perot SAW resonator including two reflectors is straightforward and it is widely discussed in the literature, see, e.g., Ref. 117. It was soon recognized t h a t SAW filters with low losses and rather wide bandwidth can be achieved by using two different resonance modes on strong piezoelectric substrates. Consequently, these devices were called double (or dual) mode SAW filters and the (rather unfortunate) abbreviation DMS filters is sometimes used; another name is coupled resonator filters (CFR's). The filter combines a few very important advantages: low loss without matching for 3-4 % bandwidth —exactly what is needed for most mobile phone R F applications, excellent suppression outside the passband, and very small size. For these reasons, CRFs have become a mass-production component. Amazingly, there are a limited number of publications 1 1 8 , 1 1 9 describing the theory of the filter. The design approaches are covered by a patent. 1 2 0 The reason is the relative complexity of the structure and the strong coupling of modes. As a result, only numerical simulation can give a correct insight into the device operation. Below we will discuss how this is done using the COM model. We will also briefly discuss one more related class of filters, so called transversecoupled filters (TCF's). These filters can be interpreted as two parallel synchronous resonators, between which there is proximity coupling, that is: an acoustic coupling due to the overlap of the transversal acoustic fields extending from the waveguide. The coupling between the resonator tracks can be optimized by changing the distance between them. Normally the distance is made very small, just a few wavelengths. The COM model is a convenient tool for the design of TCFs. 1 2 1 ' 1 2 2 ' 1 2 3 5.3.1. Coupled-resonator

filters

(CRF's)

Coupled-resonator filters are topologically similar to two-port SAW resonators, with transducers being placed between reflectors. However, the transducers have reflecting electrodes and the reflectivity is not small. This complicates the analysis: the

62

Coupling-of-Modes Analysis of SAW Devices 929 transducers not only serve t o couple the signals into the resonant cavity but they directly influence the resonant modes. Currently the most popular C R F structure, described in patent the patent of Ref. 120, includes three transducers as illustrated in Fig. 24. The structure provides larger passband than a device with only two IDTs. In this structure two symmetric longitudinal resonance modes (1st and 3rd) are simultaneously excited. The gaps D between transducers T l and T2 and gaps S between T2 and reflectors G are used t o tune the resonance frequencies. As described in Ref. 120, the following parameters must be optimized during design: • pitches pxi and px2 of transducers T l and T2 (often taken equal),

• pitches in reflectors (often taken equal in both reflectors, but 1.5% t o 2.0% greater than in the transducers),

• ratio NT2/NTI

of the numbers of fingers in transducers,

• gaps D between transducers and gaps S between transducers and gratings • aperture W. A convenient approach t o optimize these parameters is t o construct a numerical COM model of the device and to use the available standard optimization routines. Let P ( T 1 ) , P(T2\ and P< G ) denote the P-matrices of the transducers T l and T2 and the grating G, respectively. Obviously, there are many ways t o cascade the P-matrices using the cascading formulas (49)-(55). One variant is described below. First we connect the gap S to the reflectors G: tfG) = p(Q) e-XksSf

(136)

where ks is the wavenumber inside the gap S. Half of the gaps D are attached t o the transducer T l : Pi?=Pg1)e-ik°D, (137) Pa

= Pi?* e~ikDD,

(138)

p$=p^)e-ik0D,2^

(139)

P$) = Pg1)e-ikD'>/*.

(140)

Here, A;D is the wavenumber in the gap D. The second half of the gap D, as well as the grating G and the gap S are attached to the transducers T2:

11

-y11

+

p(2) _ p(T2) (. 13 P l 8 +

-

i-pp(G)Je P£2)R(G)

e

{ l-P^R(0))

63

(141)

'

\ e-ikDD/2

'

,U9x (142)

930

V. Plessky & J. Koskela

PJ22)RiG)

p(2) _ p (T2) /

p(2)_p(T2)

\

-ikDD/2

,u„x

. (P£2))W

(1U)

Finally, the resulting two-port elements, described through P-matrices P ' 1 ' and P ' 2 \ are cascaded to obtain the two-port Y-matrix (admittance matrix) of the device: 9P(1)P(1)P(2) 11-38

+

l-(Pff+P1(M?)' y _ 2o(2) . 2PfPlCPiil±Pill) +^TTTTTTrT' P£)PZ *22 - 2P 3 3 + 1-{PS> 7ZjTS

(

}

fl46 .

(146)

(2) p ( l )

U2

2R 13 *31

i-^+pfMV

(147)

(1) p(2)

v

2P:^P

*~i-(*/+kv®-

<148)

For two-track devices, standard network analysis formulas must be implemented to calculate the S-parameters of the device and to include some parasitic elements, such as inductances due t o the bonding wires and package capacitance. Together with the advice from the patent in Ref. 120, this model and reasonably accurate COM parameters are sufficient to start the design work; the rest is experience? Figure 25 shows the results of optimization of a CRF for application in CDMA Rx-channel. Typically CRFs have reasonably low losses in the passband, and excellent shape factor and stopband suppression. The sidelobe above the passband is characteristic to CRFs and it is due to the fact that, independently of resonances, the transducers "talk" to one to another. Consequently, the passband is seen on the top of a typical sine-type transducer response. Recently, the interest in CRFs has renewed due t o the discovery 53 ' 54 of the optimized 42° YX-cut-LiTa03 substrate and very thick electrodes of h/\o = 8% to 10%. From the point of view of design this results in additional difficulties, recompensed by decreased losses and a wider achievable passband. 5.3.2. Transversely coupled filters (TCP's) In transversely coupled filters two identical narrow-aperture resonators are coupled as waveguides. A typical T C F structure is depicted in Fig. 26. It includes long and narrow input and output transducers, situated at the top-center and the bottom-center of the structure and the reflectors at both ends of the structure. A characteristic feature of TCFs is the common narrow busbar for the two transducers, "Experience: the collection of the failures an individual has made.

64

Coupling-of-Modes

Analysis

of SAW Devices

780 800 820 840 860 880 900 920 940 960 980

/ [MHz] Fig. 25. Simulated response of a CRF filter for CDMA Rx-channel.

PI

1 Tfijllj

out

Fig. 26. Transversely coupled resonator filter.

65

931

932

V. Plessky & J. Koskela

grouned and connected to both short-circuited reflectors. The transducer is separated from the reflectors by spacers, which are used to tune the frequency position of the resonances. The device was invented many years ago 1 2 4 ' 1 2 5 and it is widely used for narrow band (0.1% or so) intermediate frequency (IF) filter applications. Many interesting improvements have been presented to this basic architecture. 1 2 6 The main advantage of TCFs is that there is no direct way for the SAW from the input transducer to the output. The coupling is between guided modes, and is efficient only when modes are resonantly excited. This gives both low loss at the passband and excellent rejection levels. The peculiarity of the device is that the modes of interest usually can be divided into two groups, symmetric and antisymmetric^ 1 with respect t o the center busbar. The modes are assumed t o be orthogonal eigenmodes, i.e. they do not interact acoustically (the existence of such modes is itself the result of an interaction). However, each mode is reflected from the gratings and is in this way coupled with an identical but counterpropagating mode. The total admittance of the device is created by two resonating modes, which have slightly different velocities and resonance frequencies. Careful matching is demanded to achieve low losses. The COM formalism is well suited to describing the guided modes, provided t h a t these are not drastically changed by the interaction with the electrode system. Normally this is the case for TCFs on quartz substrates. The COM theory for TCFs was presented by C. S. Hartmann and co-authors. 1 2 1 ' 1 2 2 They give a complete set of COM equations for the modes and formulas for P-matrix elements, see also Refs. 128,129. The calculated acoustic admittances are connected to the input and output of the device, taking into account the symmetry of the modes and some parasitic elements. We will not reproduce here the formulas because they are similar to those for synchronous resonators. Another paper by the same authors 1 2 3 gave an example of the design using a set of COM parameters for quartz substrates. An analytical theory for calculating the response of T C F s was derived consistently by Biryukov et al.130 In practice, TCFs are difficult to design due to the fact that the COM parameters are sensitive to the aperture of the structure and they are different for different modes. For these reasons, the precision of the design and the manufacturing accuracy are sometimes not sufficient to get devices on the correct frequency, and trimming may be necessary. The devices are often connected in series to improve suppression, but interstage matching usually cannot be avoided at low frequencies. Further development 1 3 1 ' 1 3 2 has been directed towards achieving a wider passband and balun operation, i.e. balanced input and unbalanced output. 5.4. Impedance

element

filters

(IEF's)

The admittance of a typical long, uniform resonator is illustrated in Fig. 27. The Mn reality, a small asymmetry may exist due to the anisotropy of the substrate crystal. 127

66

Coupling-of-Modes

10l

Si 101

b >*

. (a)

___y

Analysis

J1 1

-

V 800

850

900

933

p = 2 Jim Nt = 300 iV g =37 W = 64 (im a/p= 0.5

10"'

10

of SAW Devices

1000 1050 1100 1150 1200

950

/ [MHz]

A—ImYC/)

•

940

980

1020

•

1060

1100

/ [MHz] Fig. 27. (a) Admittance of a long uniform LSAW resonator, impedance element, with with heavy (h/\o=10%) aluminum electrodes on a 42°YX-cut LiTaC>3 substrate. (6) Expanded view.

67

934

V. Plessky & J. Koskela

Zsi

I in

Z S2

.—iQhn—|Q|—i EH Zv

ED ZP

EH Z P

1 owf

Fig. 28. Schematic ladder filter. S and P denote series and parallel resonators, respectively.

response is similar to that of a classic quartz bulk-wave resonator with the resonance at about 980 MHz and the antiresonance at at about 1010 MHz, with the resonanceantiresonance separation (R-a-R) being about 30 MHz. The impedance at resonance is very low, below 1 fi, while at the anti-resonance it is close to 1 kf2; such magnitude of change in impedance, three orders, is typical for LSAWs on LiTaC>3 and LiNb03 substrates in the 1 GHz frequency range. Using such a resonator as a building block, one can repeat many filter design approaches known for filters, based on the bulk wave quartz crystal resonator. This idea has been very fruitfully exploited 1 3 3 ' 1 3 4 ' 1 3 5 ' 1 3 6 , 1 3 7 to create different types of what are called SAW impedance element filters (IEFs). By cascading sections of series and parallel resonators one arrives at ladder filter design, see Fig. 28. If the resonator in Fig. 27 is used as the series arm element, the resonance of the element gives roughly the center of the passband of the filter, while the antiresonance produces a notch to the filter response above the passband. On the other hand, the resonance of the parallel element shunts the signal to ground: with the antiresonance frequency of the parallel element selected close to the resonance frequency of the series element, this results in the lower-frequency notch in the filter response below the passband. The distance between the notches is thus about double of the R-a-R separation, about 60 MHz. Consequently, a passband from 30 MHz to 35 MHz can be achieved. The COM approach allows one to optimize the admittance of the building blocks and consequently, the filter performance. In the first ladder filters the series arm resonators were usually identical, as well as those in the parallel arms, so optimization included two sets of geometric parameters for resonators: pitches, the number of fingers in the IDTs and reflectors, etc. Nowadays the tendency is to optimize all resonators separately. We will not go into details of the network design. Instead, we will try to trace how the parameters of a single resonator influence the filter performances. The expanded view in Fig. 27(6) reveals interesting small details. First of all, at frequencies close to 1050 MHz the admittance features ripples associated with the upper edge of the stopband. As discussed before, the width of the stopband is determined by the absolute value of the reflectivity of the fingers, about 22% in

68

Coupling-of-Modes

Analysis

of SAW Devices

935

this case. Such a high value is due to very thick electrodes being used. Since the antiresonance of the parallel element is close to the center of the niter's passband, the ripples at the upper edge of the stopband of the parallel element occur at the upper notch in the filter characteristics, without causing deterioration of the device performance. However, if the reflectivity were considerably smaller, the ripples would appear close to the antiresonance of the parallel element and they would result in unacceptably strong ripple in the passband of the filter. 136 Very thick electrodes on 42°-LiTa03 give a few other advantages as well: • bulk-wave radiation (starting practically immediately after the upper edge of the stopband, see Fig. 27(6)) is reduced • resistivity of the electrodes is reduced • the width of R-a-R frequency distance is increased, which gives the possibility of increasing the passband of the filters. Now, the ripples on the left side from the resonance of the series element always enter into the filter passband and manifest themselves there. If the sections of the filter are identical the ripples will be amplified. A few evident measures can be used t o avoid this: very long reflectors and weighted reflectors, as well as a frequency offset between the series elements can be used. Optimization routines can be employed on these parameters to minimize the ripples. Finally, slightly above the resonance frequency, at about 990 MHz, one can see that the conductance (the real part of the admittance) features strange behavior not described by the COM model. The impression is that something of a bell-shaped additional hill is added on the top of the expected admittance curve, 68 suggesting the presence of an additional loss mechanism. We believe t h a t this effect is due the radiation of the LSAWs into the busbars of the device. 1 3 8 , 1 3 9 ' 1 4 0 ' 1 4 1 In the filter response this radiation is manifestated as a degradation of the rectangularity of the left corner of the passband. The operation of IEFs (including ladder filters) is conceptually different from other SAW filters. The other filters work as some kind of a transformer, wherein the electric energy is transformed into acoustic wave and then reconverted back to the electric form. The frequency-dependent characteristics of the transduction process and sometimes, elements placed into acoustic channel, form the frequency response of the device. The IE filter works not as a transformer but as a switch. At resonance (in the passband) the series element has the impedance as low as 1 CI, and only 2% or so of the voltage applied to the device input is distributed to this element, with the rest being directly applied to the load. The input signal is never transformed completely into acoustic power and only a small part of the power is concentrated inside the SAW elements. This makes the power handling capability of the IE devices much higher than that of CRFs or other classic SAW filters. 142 There are numerous ways to manipulate the elements for ladder (IEF) filters. Normally these filters are designed to be self-matched to 50 Q. Network analysis 143

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shows that the static impedance of the series and parallel elements must be around this number, more exactly Zs-Zp = 2500 f22. However, the same impedance may be arrived at by connecting two identical resonators (with impedance Z) in parallel and then connecting two such groups in series: Z / 2 + Z / 2 = Z . In practice this means that the aperture and the number of electrodes in a resonator may be doubled, but a middle busbar must be introduced. Special care must be taken to ensure the correct polarity of the fingers in the respective tracks, such that the transducers excite the common symmetric waveguide mode. With this trick one can keep the same admittance while doubling the aperture and Nt, which not only gives a fourfold increase in power handling, but may be useful to reduce ripples. Of course, the opposite possibility is also available: to separate the whole length of the transducer into two equal parts and to connect the parts in series. This increases the impedance of the resonator four times. (Again, attention much be paid to the polarity of the fingers.) This strategy is much better than just decreasing the number of fingers in transducer four times. Finally, the parts of the same resonator can be such that they are not connected at all electrically, 144 if the voltage applied to them has the same amplitude and the phase shift is fixed (see an example below). Of course, special care must be taken for the polarity of adjacent electrodes and/or gaps between sections. These tricks allow the distribution of the SAW energy over larger areas in critical points of the filter, the reduction of ripples, and the decrease of other parasitic effects. This and some other advantages of ladder filters have made the approach dominant in R F filter design over the last 5 years. Compared to CRFs, ladder filters usually have • better losses • wider passband • incomparably higher power handling capability. As a drawback, the suppression level is determined by a ladder of capacitances and is normally not very good (-25 dB to -45dB). The ripples in the passband normally increase in IEFs if one tries to achieve good rejections -CRFs have no such problems. The use of very thick electrodes in CRFs allow one to decrease losses and nowadays CRFs are becoming a popular design approach again. The advantage of CRFs is also that they can be designed for a balanced/unbalanced environment, which evidently is not possible for IE networks. 5.4.1. Balanced bridge filters

(BBF's)

One of the drawbacks of the ladder filters is the relatively poor rejection level. The rejection provided by voltage division on the capacitor sections is independent of frequency and has no tendency to improve with the increase of the detuning from the passband. For the balanced environment, a balanced bridge SAW IEF was

70

Coupling-of-Modes Analysis of SAW Devices 937

Fig. 29. Balanced bridge filter. proposed by Kondratiev and Plessky. 137 In this filter two pairs of the impedance elements are connected in a balanced bridge configuration, as depicted in Pig. 29. In the simplest case the static capacitances can be chosen equal for all four elements. To provide the resonance frequency of IE1 close to the anti-resonance frequency of IE2, the resonance frequencies are shifted as for ladder filters. The device works by exploiting the strong misbalance at the passband frequencies: the signals pass with low losses through the IE1 elements, having low impedance, while the other elements, having very high impedance at the passband frequencies, cannot shunt the filter. The voltages transmitted to the output through the static capacitances are cancelled, and out of the passband the rejection grows monotonically. The equivalent elements IE1 (correspondingly IE2) of the BBF, not connected directly electrically, can be designed as a part of the same resonator. So, the section of the balanced bridge filter can comprise only two resonators. 1 4 4 To achieve better rejection two sections of BBF may be cascaded. A few highly symmetric layouts were found by Kondratiev and Plessky, 145 which are balanced also with respect to parasitic capacitances. Note that the operation of BBF does not require a well-pronounced antiresonance. This is an important point: ladder filters are never designed on quartz since an extremely long synchronous resonator is needed to achieve an antiresonance. However, the difference of impedances is sufficient to form a BBF passband filter characteristics. 5.4.2. Notch filters In some applications a filter is needed to suppress signals in a particular frequency range. In the simplest case a synchronous resonator can be used as such a filter, if one connects it in series from the input to the output (the notch will appear at the anti-resonance frequency due to the high impedance disconnecting the output from the input) or in parallel (the shunting effect at the resonance frequency is used). More sophisticated filters have been proposed by Hartmann, 1 4 6 and recently by Lorenz and Thompson. 1 4 7 We mention this class of filters to stress that historically

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the impedance elements were first used in these notch filters. 5.5. COM

analysis

of filter tolerances

to technological

variations

The design and operation of the discussed transducers, reflectors, resonators, and resonator filters are all based on periodic structures assumed to consist of ideal electrodes. However, in reality the manufacturing processes have difficulties in accurately producing the electrodes (typically made of aluminum), especially in R F filters where the dimensions of the structures approach the technological limits. Consequently, the sensitivity of a device to technological variations is of extreme importance in mass-production applications where high device yield is crucial. Besides serving as a tool for filter design, the COM model also enables easy evaluation of the manufacturing sensitivies. Characteristic to the lithographic processes is the fact that, although there are technological variations in the thickness, width and shape of the electrodes from the desired values, the variations remain almost the same over large wafer areas and they are practically constant in any single device. The pitch can be controlled much more accurately than the electrodes themselves, and it is usually of little or no concern. In this case, the COM model of the device remains equally valid, with only the values of the parameters being slightly shifted. The COM parameters and their dependence on the properties of the electrodes were already discussed in Section 2.3; for an example, see Fig. 14. The consideration is now reviewed from the point of view of manufacturing. Changes in the thickness of the aluminum electrodes, h, usually result in changes of the velocity v and the reflectivity KP, while the effects on the transduction coefficient and the capacitance tend t o be weak. As an exception, the electromechanical coupling of STWs increases with the electrode thickness. Note that the COM parameters depend on the relative electrode thickness h/\, such that the same absolute thickness variation Ah results in different changes in substructures with different pitches. In synchronous uniform resonators the resonance occurs at an edge of the stopband, such that the resonance frequency is

*=s(1+S)-


In most substrates, including the LSAW cuts on LiTaOs and LiNbOs, an increase in the electrode thickness decreases the velocity and increases the reflectivity. From Eq. (149) we see that both contributions tend to shift down the resonance frequency. Changes in the electrode width a, or the metallization ratio a/p, influence the velocity and the reflectivity as well as the transduction coefficient and the capacitance. Usually, an increase in the metallization ratio slows the wave and increases the electromechanical coupling and the capacitance. Thus, the antiresonance frequency is also shifted. Whereas changes in the electrode thickness shift mainly the resonance frequency, changes in the electrode width shift both the resonance and the antiresonance. Changes in the shape of the electrode are more difficult

72

Coupling-of-Modes Analysis of SAW Devices 939 of classify, but among the parameters the reflectivity is the most sensitive. The velocity depends mainly on the amount of the total mass, whereas the transduction coefficient and the capacitance depend mainly on the surface area of the electrode. If the fabrication process is stable and well known, the distribution of the values of the COM parameters resulting from the process may be analyzed statistically, and the device yield may be estimated by running the model with different combinations of the COM paramaters. Concrete examples of the analysis of technological sensitivity on, e.g., quartz in Ref. 148. 5.6. Important

issues

of SAW filter

design,

not included

in this

paper

"One cannot embrace the non-embraceable" said one home-grown philosopher. In practice, the design of a SAW filter begins with the analysis of the filter specification. The choice of the design approach is dictated by numbers written there: some (rare) specifications can be easily met using different design approaches, some are difficult for all known designs. Somewhere in-between these two extremes one often opts for ladder (IE) filters of CRFs, if low loss is demanded. We have tried to show how these popular design approaches can be realized using the COM model. We have no space to discuss many other brilliant design ideas, such as reflector-based filters and ring filters; the COM model is suited to analysis of many such cases as well. Although optimization routines may vary a few dozens of geometric and layout parameters, they give reliable results only if the COM parameters are accurately known. Finally, the parasitic elements of packaged devices: bond wires, pin capacitances, etc., must be kept in mind. Some of these elements give almost positive effects. For example, wire bonds can improve the loss level in ladder filters a little, and even increase the passband. Unfortunately, such gifts are rare. In most cases the mutual inductances of the bond wires (transformer effect) dramatically increase the direct electromagnetic signal coming from the input to the output (feedthrough), and additional parallel capacitances increase the passband ripples. There have been attempts to use intensive numerical methods 1 4 9 ' 1 5 0 to model the package parasitics. The results are encouraging, although they still cannot be used together with the optimization routines. 6. Conclusions a n d F u t u r e Challenges The COM model is an excellent tool for the analysis and design of many types of SAW devices which can be subdivided into uniform periodic sections of transducers, reflectors, and some other elements. The model describes the elementary sections by algebraic formulas, which makes the calculations extremely fast and enables the use of optimization routines. We have tried to show in this review t h a t this area is now in dynamic development. The tools are developed in parallel with the object to which they are applied. However, it would be too early to say that all problems are solved. Some significant problems remain, for example, in the extension of the

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COM model for shear horizontal surface-acoustic waves and in the inclusion of the waveguiding effects in the formalism. Is there life after COM? What will replace the COM model in future? It is difficult t o answer. As a general simplified description of waves of different physical nature in periodic media the model will be used always, but for exact design the tendency will be to use the numerical F E M / B E M methods, at least for the determination of the COM parameters. But as a tool, the popularity of the COM model depends on the subject -filters for mobile communications. For a few years there is no clear alternative to R F SAW filters in mobile phones -meaning further complication of the specifications, higher operation frequencies, 151 further sophistication of filters, and further improvement of models to design them. Acknowledgments We are grateful to all our colleagues who have contributed during many years to better understanding of the topics discussed in this paper. Our special thanks go to Dr J. Heighway for the difficult task of reading the manuscript. The second author (JK) acknowledges Helsinki University of Technology for a postgraduate Research Scholarship and the Academy of Finland for support through a fellowship within the Graduate School in Technical Physics. References 1. C. C. W. Ruppel, W. Ruile, G. Scholl, K. Ch. Wagner, and O. Manner, "Review of models for low-Loss filter design and applications", in Proc. 1994 IEEE Ultrason. Symp., pp. 313-324. 2. M. Buchner, W. Ruile, A. Dietz, and R. Dill, "FEM analysis of the reflection coefficient of SAWs in an infinite periodic array", in Proc. 1991 IEEE Ultrason. Symp., pp. 371375. 3. U. Rosier, D. Cohrs, A. Dietz, G. Fischerauer, W. Ruile, P. Russer, and R. Weigel, "Determination of leaky SAW propagation, reflection and coupling on LiTaOs", in Proc. 1995 IEEE JJltrason. Symp., pp. 247-250. 4. T. Sato and H. Abe, "Propagation of longitudinal leaky surface acoustic waves under periodic metal grating structure on lithium tetraborate", IEEE Trans. Ultrason., Ferroelect, Freq. Contr. 4 5 (1998) 394-408. 5. P. Ventura, J. Desbois, and L. Boyer, "A mixed FEM/analytical model of the electrode mechanical perturbation for SAW and PSAW propagation", in Proc. 1993 IEEE Ultrason. Symp., pp. 205-208. 6. P. Ventura, J. M. Hode, and M. Solal, "A new efficient combined FEM and periodic Green's function formalism for the analysis of periodic SAW structures", in Proc. 1995 IEEE Ultrason. Symp., pp. 263-268. 7. P. Ventura, J. M. Hode, "A new accurate analysis of periodic IDTs. built on unconventional orientation on quartz", in Proc. 1997 IEEE Ultrason. Symp., pp. 139-142. 8. K. Hashimoto and M. Yamaguchi, "Precise simulation of surface transverse wave devices by discrete Green function theory", in Proc. 1994 IEEE Ultrason. Symp., pp. 253258. 9. K. Hashimoto, G. Endoh and M. Yamaguchi, "Coupling-of-modes modelling for fast and precise simulation of leaky surface acoustic wave devices" in Proc. 1995 IEEE

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35. 36.

37. 38. 39.

40.

41. 42. 43. 44. 45. 46. 47. 48.

49.

50. 51.

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International Journal of High Speed Electronics and Systems, Vol. 10, No. 4 (2000) 949-1015 © World Scientific Publishing Company

T H E O R Y A N D A P P L I C A T I O N S OF G R E E N ' S F U N C T I O N S

ALI R. BAGHAI-WADJI" Materials Physics Laboratory, Helsinki University of Technology P. O. Box 2200 (Technical Physics), FIN-02015 HUT, Finland

In this chapter it is shown that three dimensional governing- and constitutive equations in transversally inhomogeous piezoelectric media can be diagonalized. A symbolic notation has been introduced which allows to perform the diagonalization simply by inspection. Diagonalized differential equations transform into eigenvalue forms in Fourier domain. Solving for the corresponding eigenpairs, the construction of various Green's functions has been demonstrated by several examples. In addition novel ideas for the calculation of self-actions in the boundary element method have been discussed. The work consists of four sections. Following a brief introduction in the first section, the diagonalization procedure is described in the second section. The presented methodology is a refinement of the author's ideas which were presented in various short courses. The third section on Green's function theory and the calculation of self-actions in the boundary element builds upon the author's lecture notes. The fourth section briefly summarizes our discussion and suggests directions for possible future research.

°The author is presently on leave of absence from Vienna University of Technology, Institute E366-B, GufihausstraBe 27/366B, A-1040, Wien, Vienna, AUSTRIA.

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Baghai-Wadji

1. I n t r o d u c t i o n For nearly two decades the boundary element method (BEM) has been the method of my choice for solving boundary value problems. 1 - 5 BEM alone or in conjunction with other popular numerical methods, such as finite difference method (FDM) or finite element method (FEM), can serve to tackle a large number of engineering problems, reliably and efficiently. As long as we are dealing with linear problems, BEM may offer distinct advantages compared with the FDM and FEM. Using BEM the dimensionality of the problems reduces by one, leading to smaller impedance matrices. However, for obtaining matrices with a reduced size we trade a number of drawbacks which can be challenging: (i) The resulting impedance matrices are dense as opposed to the corresponding matrices obtained from FDM and FEM. (ii) For the application of the BEM surface integral equations must be formulated, which involve certain fundamental solutions, called Green's functions. 6 - 9 The construction of Green's functions and their spatial derivatives can be challenging, (iii) We will refer to the elements of the impedance matrices in the BEM as the (mutual) interaction elements. The diagonal elements will be called self-action elements. In most applications the calculation of the self-action elements is extremely tedious if not particularly hard. In Ref. 9 we presented a unifying procedure for the treatment of the problems mentioned in (ii) and (iii); some selected topics will be covered in Section 3 of this work. The complexity of the piezoelectric equations in inhomogeneous media has been the driving force for the development of the symbolic notation which is presented in Section 2. The diagonalization is not a new technique. W h a t is new is the proposed symbolic technique, and the fact that this technique applies to problems in three dimensions, and finally the fact that it covers the analysis of transversally inhomogeneous media. Concerning the denseness of the impedance matrices mentioned in (i), it has been known that wavelets, or generally, locatized expansion functions, may provide some help. We also have looked at this problem, however, from a different point of view t h a n those reported in literature, and obtained promissing preliminary results. 1 0 Space limitation does not allow to discuss any of the results obtained more recently. The IEEE Ultrasonics Conference Proceedings are a good source to find further examples, and additional references to this author's work. Concerning the diagonalization the reader might find useful information in Refs. 11-15. W i t h regard to the application of Green's functions in device modeling and simulation the discussions in Refs. 16-22 may be helpful. 2. O n t h e Diagonalization of P i e z o e l e c t r i c Equations in Transversally Inhomogeneous Media There are two notations used for the manipulation of the governing and constitutive equations in piezoelectric media; the tensor- and matrix notation. While physicists commonly prefer to use the tensor notation, engineers mostly feel more comfortable with the matrix notation. In this section, building upon the matrix notation, we present a novel symbolic method for fast and convenient manipulation of the piezoelectric equations. Simplicity of calculations and the design of fast algorithms have been the driving force for the development of this technique. It will be shown that the piezoelectric equations (like several other fundamental equations in mathematical physics) can be reduced to a structured system of partial differential equations (PDEs), which involves a matrix differential operator £ . In the Fourier domain £ transforms into an algebraic matrix L. For general piezoelectric media C and L are comparatively complex (8 x 8) matrices. The author's efforts to simplify the manipulatory calculations have suggested the definition of three (6 x 3) matrices N j (i = 1,2,3), which can be seen as a generalization of the conventional outward unit normal vectors n* (i = 1, 2, 3).

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The unique properties of N j allow us to speed up the manipulatory calculations by orders of magnitude. The hand calculations can be performed simply by inspection. In the following analysis we first define N j and then establish their properties. Finally we use these matrices to diagonalize the piezoelectric equations. Not only the piezoelectric equations but also every system of PDEs in mathematical physics we have investigated so far, possesses an equivalent diagonalized representation. This fact motivates the following statement: Linearized partial differential equations, as mathematical models for physically realizable systems, can be diagonalized. The existence and construction of diagonalized forms have been demonstrated for a variety of equations in Ref. 9; e.g. the Laplace's equation for electrostaticand magnetostatic problems, the Maxwell's equations, the Newton's equations, the piezoelectric equations, and the piezoelectromagnetic equations? In this work, however, we focus on the piezoelectric phenomenon and introduce a recipe for the conversion of the associated equations into an equivalent diagonalized form. The calculations will be carried out in three spatial dimensions. Qualitative Description of the Diagonalization: Given a certain boundary value problem in terms of a set of PDEs, consider a point p, and associated with it, a distinguished direction in the space. Let the z—axis denote this direction? Assume a (tangent-)plane P passing through the point p, to be locally perpendicular to the z—axis. Denote the spatial variables in the P—plane by x and y. At point p traverse in z—direction across the P—plane, and determine the interface conditions on this plane. Determine all the irreducible {§) and derived variables (f) entering the interface equations. Call these variables the essential variables. Refer to all the remaining variables in the governing and constitutive equations as the nonessential variables. The diagonalized form only involves the vector ( $ , ? ) ' . d This fact can be exploited for performance enhancement of numerical methods 1 1 . In the FEM the diagonalization automatically leads to the geometrical and natural boundary conditions; in the FDM the diagonalization suggests the development of novel stencils; and finally in the BEM the diagonalization offers numerous valuable possibilties for designing accelerated and robust numerical techniques. Choosing the z—axis as our distinguished direction, the diagonalized form takes on the generic form in (1). £(x,v)(

f

J (z, V, z) = — (

-

)(x,y,z)

(1)

The matrix differential operator L depends on the local transversal variables x and y. In addition £ may depend on the time variable t, and also on various material parameters. The material parameters may locally depend on transversal variables. According to (1) the rate of change of ( ^ , r ) * at a point p in the z—direction, is uniquely determined by the functional behavior of ( ^ f ) * on the P—plane in the neighborhood of this point. It is exactly this property that allows us to improve the performance of the numerical techniques and to design efficient algorithms. Equation (1) in the Fourier domain reads 6

This author is presently investigating the diagonalization of the heat-, mass transfer-, and the Schrodinger equation with spatially varying coefficients. c In actual problems either the material inhomogeneity or the geometry of the problem suggests the choice of the distinguished direction. d The superscript t denotes transposition.

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952 A. R. Baghai-Wadji

i(*i,*a)(

*

)(ki,h)

=

X(k1,k2)

P

1

(ki,k2),

(2)

which is an eigenvalue equations for the eigenvector ($?, T ) ' and the associated eigenvector A. With reference to the isometry property of the Fourier transform, we may call the diagonalized forms differential eigenforms. A three-step procedure allows the conversion of the governing and constitution equations into equivalent differetial eigenforms: • identification of the essential field variables, • partition of the irreducible and derived variables into the essential and nonessential variables, • elimination of the nonessential

variables.

In order t o carry out these steps we have developed a simply-by-inspection symbolic multiplication and index operation technique. W h a t follows should provide the reader with the tools necessary for the manipulation of piezoelectric equations. Similar ideas apply to many other PDEs 9 . 2 . 1 . A symbolic equations

notation

for

convenient

manipulation

of

piezoelectric

Preparatory Considerations: Several definitions seem necessary in order to simplify our manipulations. We next establish these definitions. 2.1.1. Orthogonal unit vectors in R 3 In R 3 we define three unit column vectors rij (i = 1,2, 3)

ni

"1' 0 0

n2 =

"0 ' 1 0

n3 =

"0 " 0 1

(3)

with the orthonormality relationship in (4). :

H"-j

$a

(4)

Sij is the Kronecker delta symbol. Both sides of the correspondence sign in (5) convey the same information. rii o (i)

(5)

The subscript of a certain unit vector specifies this vector uniquely: The symbol (i) represents a 3 x 1 unit (column) vector with its ith component being unity. Similarly, the representation in (6) suggests itself. n< o (i)' The symbol (i)1 signifies a 1 x 3 unit (row) vector with its ith unity.

86

(6) component

being

Theory and Applications of Green's Functions 953 2.1.2. Orthogonal unit vectors in R 6 In R 6 we denote the unit column vectors by hj (i = 1, ..,6). I13, for instance, has the form

h3 =

(7)

It turns out that for the symbolic multiplication and the index manipulation technique, which we are developing here, three 6 x 3 matrices N , (i = 1,2,3) play a crucial role. The following discussion details the structure and construction of these matrices. In what follows we do not claim mathematically to be rigorous. However, considerable effort has been made to be consistent, and to provide plausible explanation for the symbols that we have introduced. I and O stand for the unity- and null matrix in R 3 x R 3 , respectively. 2.1.3. Construction

0/N1

The recipe for the construction of N i comprises five simple steps. Step 1: Decompose the Unity Matrix I Express I as the sum of two orthogonal matrices as shown in (8). 1 =

1 0 0 " " 0 0 0 0 0 0 + 0 1 0 0 0 0 0 0 1

(8)

Step 2: Factorize Factorize the second matrix at the right-hand side of 8 as the product of a symmetric matrix with itself. This factorization is unique. 0 0 0

0 0 0

0

0 1 0 0 1

0 0 1

0 1 0

0 0 0

0 0 0 1 1 0

(9)

Substituting (9) into (8) yields 1 =

1 0 0

0 0 0 0 0 0

0 0 0

+

0 0

0 1 1 0

0 0 0

0 0 0 1 1 0

(10)

with the orthogonality property in (11). 1 0 0

0 0 0 0 0 0

0 0 0

0 0 0 1 1 0

o

(11)

We call the first matrix at the left-hand side of this equation the main, and the second matrix its orthogonal complement. Step 3: Embed the Main Matrix in R 6 x R 3

87

954

A. R.

Baghai-Wadji

In order t o embed the main matrix in R 6 x R 3 , we append zeros to its constituent column vectors as indicated in (12).

1 0 0

0 0 0

1 0 0 0 0 0

0 0 0

main matrix

0 0 0 0 0 0

0 0 0 0 0 0

(12)

augmented main matrix By way of construction, we have the following relationship between the non-zero column vectors in the main matrix and the corresponding augmented matrix: ^ i I main matrix

H I augmented matrix

In particular we have in (12): * l l | m a i n matrix

>' "11augmented matrix

Step 4- Embed the Complement Matrix in R 6 x R 3 In order to embed the orthogonal complement matrix in R 6 x R 3 , we add zeros to its column vectors as shown in (13).

0 0 0

0 0 1

0 0 0 0 0 0

0 1 0

complement matrix

0 0 0 0 0 1

0 0 0 0 1 0

(13)

augmented complement matrix Here, we have the following relationship between the non-zero column vectors in the orthogonal complement matrix and the corresponding augmented matrix: **i I orthogonal complement matrix

'* " i + 3 I augmented matrix

In particular we have in (13):

H3|main matrix^^" h61 augmented matrix ^ 2 | m a i n m a t r i x 1 — ^ *^5 (augmented matrix

Step 5: Add the Augmented- Main and Orthogonal Complement Matrices Adding the augmented matrices in (12) and (13) completes the construction of the matrix N i :

Theory and Applications of Green's Functions 1 0 0 0 0 0

Nx

0 0 0 0 0 1

0 0 0 0 1 0

955

(15)

Technically, the construction of N i amounts to positioning the main matrix on the top of its orthogonal complement. We may symbolize N i by [hi h,6 b.5], or even more compactly by (1 6 5). We summarize the steps which led to the representation ( 1 6 5) using the following (self-explanatory) short-hand notation. Since there is no risk of ambiguity, 0 denotes in (16) a 3 x 1 as well as a 6 x 1 null vector, as the case may be. I = [ n 1 , 0 , 0 ] + [0,n 2 ,n3] = [n 1 ,0,0] + [0,n3,n 2 ][0,n3,n 2 ] I<+[ni,0,0]e[0,ns,n2] N i = [h 1 ,0,0] + [ 0 , h 6 , h 5 ] = [ h 1 , h 6 , h 5 ] N 2 o (1,6,5)

(16)

The notation a © b means: consider a and b. Each number in (1 6 5) signifies a 6 x 1 unit column vector, and carries two informations through its position in (1 6 5) and through its numerical value. Example: the number 6, being the second member in this set, and representing h6, indicates that we are addressing the second column, and that the sixth component of this column is unity. 2.1.4. Construction

of N2 and N3

Similarly, the relationships in (17) can be established. 0 1 0 0 0

+

0 0 1

0 0 0

1" 0 0

" 0 0 1 0 0 0 1 0 0

(17a)

0 0 0 ' 0 0 0 0 0 1

+

" 0 1 0

1 0 0

0 " " 0 1 0 1 0 0 0 0 0 0 0

(17b)

0 0 0

0

N 2 and N 3 in (18) is evident.

N2

' 0 0 0 0 0 1

0 1 0 0 0 0

0 " 0 0 1 0 0

N3

" 0 0 0 = 0 1 0

0 0 0 0 1 0 0

" 0 1 0 0 0

(18)

Analogously, we represent N 2 and N3 in the above-mentioned abbreviated form, and summarize our results as follows:

956 A. R. Baghai-Wadji N i -H- (1 6 5)

N 2 f> (6 2 4)

N 3 o (5 4 3)

(19)

For completeness we describe the steps leading to (6 2 4) and (5 4 3) in terms of the short-hand notation introduced earlier. I = [0,n2,0] + [ n 1 , 0 ! n 3 ] = [0,n 2 ,0] + ^ 3 , 0 , ^ 1 ^ 3 , 0 , 1 1 ! ] I « [0,n2,0] e [ n 3 , 0 , n i ] N 2 = [0,h 2 ,0] + [h 6 ,0,h4] = [ h 6 , h 2 , h 4 ] N 2 o (6,2,4)

(20a)

I = [0,0, n 3 ] + [ n i , n 2 , 0 ] = [0,0, n 3 ] + [ i ^ n ^ O H n ^ n ^ O ] I o [0,0,n3]©[n2lni,0] N 3 = [0,0, h 3 ] + [h 5 ,h 4 ,0] = [ h 5 , h 4 , h 3 ] N 3 o (5,4,3)

(20b)

Furthermore, we establish the following representations for the transposed matrices N ' :

N< *-> J 6 J N | o I 2 1 N | <* I 4 J .

(21)

The numbers in these brackets signify 1 x 6 unit (row) vectors. In our construction the relationships in (22) are valid (i = 1,2,3). N*Ni = I

(22)

As will be clear shortly, the correspondences in (5) and (19) are the only information needed, to perform the symbolic multiplications and index manipulations announced earlier. 2.2. Differential

operators

2.2.1. The nabla operator Based on our convention from the previous subsection the nabla operator and its transpose can be written in the forms given in (23). V = mdx + n2dy + mdz l

V* = n i 8X + n 2dy+

2.2.2. Auld's divergence-type

n|fl z

(23a) (23b)

operator

Auld's divergence-type operator 2 3 , given in (24), considerably simplifies the manipulations of the piezoelectric equations.

90

Theory and Applications of Green's Functions

V=

dx 0 0 0 0z 8y

0 By

957

0 0 dz

0 dz dy 0 dx <9X 0

Using N j , the following relationships are immediately obvious.

Y = N A + N a a s + N3d2 Y* = Ni ax + ~N2dy + N3<92

(25a) (25b)

Comparing (23) and (25) it becomes clear why we have referred to Nj as generalizations of Ilj. 2.3. Field

variables

We distinguish between irreducible, derived, essential and nonessential field variables. 2.3.1. Irreducible field variables These are the field quantities from which all the other field variables can be derived. Adopting the quasi-static approximation 2 3 , the irreducible variables in the linear theory of piezoelectricity are the following: the scalar electric potential ip and the mechanical displacement vector u. In a conveniently chosen (x, y, z)— cartesian local reference frame the components of u will be denoted by Uj, U2 and U3. 2.3.2. Derived field variables These variables can generally be obtained by a linear combination of the spatial derivatives of the irreducible variables. Examples for the derived variables are the components of the electric displacement vector and the elements of the stress tensor. 2.3.3. Essential field variables We may speak of essential field variables with respect to a surface or a specific direction. As an example, consider the plane x = 0 in the local coordinate system (x, y, z). We pose the following question: which field varibles enter into the interface conditions if we pass through this plane along the x — axis? We find that the aforementioned irreducible variables, together with the components Z) 1; T 1 1 ; T21 and T31 enter the interface conditions. D\ denotes the component of the electric displacement vector in the ar-direction, while the remaining quantities refer to the stress components acting on the plane x = 0 and being in the x~, y—, and z— direction. Therefore, with respect to the z-axis, the essential variables are: tp, « i , U2, U3, £>i, T11, T21 and T31 in our interface conditions. Analogously, considering the plane y = 0 in the same local coordinate system, we find that in addition to the irreducible variables ip, ui, U2 and U3, we have D2, T\2, T22 and T32. Therefore, the essential variables with respect to the y-axis are:
91

958

A. R.

Baghai-Wadji

2.3.4. Nonessential field variables Any variable which enters the governing and constitutive equations and is not essential will be referred to as a nonessential variable. Remark: The reader should be reminded that diagonalization with respect to a direction automatically determines the essential field variables on the tangent plane associated with this direction. 2.4. Constitutive

equations

2.4.1. Dielectric displacement

vector

D = rijZ?! + n2D2 + n 3 £> 3

(26)

The projection of D onto the a;-axis is given by (27). D1=n\D

(27)

A relationship between D and the irreducible field variables can be established by using the constitutive equation in (28). D = etS + gE = e%u - gVip

(28)

e and e denote the (6 x 3) piezoelectric- and (3 x 3) dielectric matrix, respectively. In transition from the first to the second equation we have adopted Auld's notation for the strain S, i.e. S = Vu, and the equation E = — V! = n'je'Yw - n\gV
(29)

Furthermore, substituting for V and V we arrive at the result in (30). A = nie* [N1(9X + N2dy + lSS3dz} u -n\g

[ n A + n2dy + n3dz]
(30)

The form in (30) suggests the definition of the hybride vector # according to (31).

* =

u

(31)

Using (31) and appropriately collecting the terms in (30) we obtain (32). £>i = [ n i e ' N i

- n ^ i ] &•#

+ [n' 1 e*N 2

- ni£n2] d „ *

+ [11*^3 - n k n 3 ] a 2 f

92

(32)

Theory and Applications of Green's Functions

959

It is instructive to consider the explicit forms of the terms n j e ' N i and n\§p.i as examples. (33)

nJe'Ni = (eri^Ni = (N'ein)' At this point we demonstrate our symbolic multiplication tion, announced earlier. First the " h a r d " way: en

Nfeni

1 0 0 0 0 0

0 0 0

0 0 0

0 0

e2i e3i e4i

0 1 1 0

esi e6i

and index

ei2 e22 e32 e42 e52 e62

ei3 e23 e33 e43 e53

manipula-

1

o o

e63 _

en '

1 0 0 0 0 0

0 0 0

0 0 0

0 0

e-2i

0 1 1 0

e3i e4i

" en

=

e6i

(34)

esi

e6i

Symbolic Multiplications and Index Operations: We associate with N ' the numbers 1, 6 and 5 and with n\ the number 1. We observe that the result in the last equation can be written immediately without performing the intermediate calculations. Upon "symbolically multiplying" the representations for N ' andrii we obtain the indices 11, 61 and 51 "index manipulations:"

(35)

Finally using (34) in (33) we obtain (36) by transposition. (36)

n ' j e ' N i = [en e 6 i e51] A similar reasoning leads to the result in (37). n ' i £ m = (1)*£ (1) = (1 0 0) £

0 0

= en

(37)

with the obvious sysmbolic multiplication (index manipulation) given in (38). ( l ) f ( l ) = 11

(38)

Upon "symbolically multiplying" the representations for n ' and rii we obtain the index 11. Finally, by following the above rules, we obtain the following results for the remaining terms in (32) simply-by-inspection:

93

960 A. R. Baghai-Wadji n'je'Na = [e6i e21 e 41 ]

(39a)

n^e'Na = [e5i e 4 i e 3 i]

(39b) (39c)

n k » j = tij

The reader might appreciate the efficiency of this simply-by-inspection symbolic notation, already at this stage of calculations. However, in order t o fully recognize the effectiveness of this technique we proceed to the derivation of the expressions for the stress components acting on the, say, x-plane. 2.4.2. Stress components on x-plane Following Auld's concept 23 , the stress components can be arranged in a 6 x 1 "vector" f: T=(T1,T2,T3,Ti,T5,T6)t.

(40)

The components of T are defined as follows: Ti = Tu, T2 = T22, X3 = T33, T4. = T23 = T32, T5 = T13 = T31 and T% = T12 = T2\. Employing N 4 it is not difficult t o see t h a t (41) is valid. T = N i f i 4- N 2 f 2 4- N 3 f 3

(41)

The quantities fj (i = 1, 2,3) are defined in (42).

n

T6 T5

' T5

T6 '

Ti f2 =

T2 T4

T3 =

T4 T3

(42)

Using (40), and the far left equation in (42), recognizing the indices 1, 6, and 5, and associating them with the matrix N j , it is easy to see that the "projection" of T onto the a;-plane, i.e. f i , is given by (43). N\T

= n

(43)

A relationship between f and the irreducible field variables may be established by using the constitutive equation in (44). f = C S - e E = C ^ u 4- e V ^

(44)

C is the 6 x 6 elastic stiffness matrix. Using this result in (43) we obtain (45). ft = N i C ^ u 4- N\ eVip

(45)

Substituting for V. and V results in (46). f! = N * C [Nifi, 4- N 2 a y 4- N 3 a z ] u 4-N^e [ni^x 4- n2dy + n 3 9 z ] tp

94

(46)

Theory and Applications of Green's Functions

961

Rearranging and making use of the vector $ , defined in (31), lead to (47). f^pMiCNi

Nieni]0x*

+ [N'CN2

N\en2]dy$

+ IN5CN3

N'ensja^

(47)

As an exercise we .consider the terms N j C N j and N ' e r i j (j=l,2,3) in greater detail. N ' C N j : The matrices N*, C and N j have dimensions 3 x 6, 6 x 6 and 6 x 3 , respectively. For, say, j = 2, a brute force multiplication leads to (48). Cl6 C66 C56

N'jCNa

Ci2

Cn C"64 C52 C54

(48)

CG2

Let us interpret this result in the light of our symbolic notation. The term N 1 C N 2 may be represented by C( 6

2

4 ),

where we realize that the "symbolic multiplication" of the indices already provides the indices of the elements in the matrix at the right-hand side of (48):

2

4)

16 66 56

12 62 52

14 64 54

(49)

Furthermore, we can easily convince ourselves that the result in (50) is valid. 1 6

N'en,- =

e (j)

j = 1,2,3

(50)

The involved matrices in our calculations can be constructed simply by inspection. 2.4.3. plane

Spatial variation

of essential variables in direction normal to the

tangent

We now combine the equations for fi and D\ to obtain (51). N*CN! rije'Ni

Nlenj —rijerii

a**

+

NiCN2 n^e'^

Nien2 -n^gn2

dy*

+

NiCN3 n^e'N3

N'jens -n^n3

az*

-Di

95

(51)

962

A. R.

Baghai-Wadji

It is instructive to define the vectors f j and the matrices M y , as given in (52) and (53), respectively. Ti

r4 = My =

(52)

Di

N'CN,-

N'en,-

(53)

i,j = 1,2,3

Alone the ability to write down explicit forms of the various M y simply by inspecting the indices i and j , should convince the reader of the usefulness of this manipulatory technique. Using (52) and (53), (51) can be written in the compact form given in (54). Ti = M u d * * + M12dyV

+

M13dzV

(54)

Analogously we can show that the following relationships hold true. f i = M i i d x * + Mi2dv$

+ Mi3dz$

i = 2,3

(55)

Using numerical calculations it can be shown that for commonly used piezoelectric materials the inverse matrices (i = 1,2,3) M ^ 1 e x i s t / Multiplying the equations for r» from the left by M ^ 1 , and rearranging, results in the following equations. 9«* = M ^ f x - MY11M12dy$ %$ = M£f2 %$ = M ^ f

-

M ^ M w M

(56a)

1

(56b)

1

(56c)

- M ^ M a A * - Ma M23az* 3

- M ^ M a i a . f - Mi3 M32ay*

Focusing on (56a), we rewrite it in the form given in (57).

[-M^M12dv

- M ^ M ^ a , ] * + [M- 1 ] f1 =

dj

(57)

Inspecting (57), the introduction of the 4 x 4 matrix operators £ ° : and C\2 in (58) suggests itself. £?! = - M ^ M ^ L\2 = M ^

1

- M-1M13az

(58a) (58b)

e

For nonpiezoelectric elastic materials and, dielectrics, the existence of the associated (reduced) inverse matrices M ~ x follows from the positive definiteness of the elastic stiffness- and the dielectric matrices. •fFor piezoelectric materials we can say that the existence ofMTT (i = 1,2,3) is a necessary condition for the construction of diagonalized forms. Therefore, we refer to the conditions which derive from the existence of M^~ as the realizability conditions for the piezoelectric materials. In other words, we may say that those materials for which the matrices M ~ (i = 1,2,3J do not exist, are not physically realizable.

96

Theory and Applications of Green's Functions

963

Using these definitions (57) results in (59). £ n * + £?2fi=0*tf

(59)

So far we have merely used the constitutive equations in piezoelectric media. The next two subsections complete our analysis by considering the governing equations. However, before proceeding further we interpret the result in (59). Let x = 0 be a tangent plane in a local coordinate system. As pointed out earlier the essential variables on this plane are the components of the vectors $ and Ti. Our goal is to express the a;—variation of the vector ( ^ f i ) ' in terms of (^?,Ti)* and its derivatives with respect to the transversal spatial variables in the tangent plane: Obviously (59) is an expression for dx$. In what follows we derive the corresponding expression for dxVi. 2 . 5 . Governing 2.5.1. Laplace

equations

in standard

form

equation V'-D = 0

(60)

Substituting for V ' we obtain the results given in (61a) and (61b). [n\dx + n^dy + n\dz\D dxDl

= 0

+ 0yD2 + dzD3 = 0

(61a) (61b)

In transition from (61a) to (61b) we have used the definitions in (62). A = nlD

(62)

2.5.2. Equations of motion According t o Auld's convention 23 , the equation of motion in a source free piezoelectric continuum can be written in the following form:

p stands for the mass density. We substitute for .V* t o obtain (64a) and (64b):

[N\dx + Nldy + N | a z ] f = pfLu

(64a)

2

d _ dxfi + dyT2 + dzT3 = p ^ 5 In transition from (64a) to (64b) we have used the definitions in (65)

97

(64b)

964

A. R.

Baghai-Wadji

N'T

2.6. Governing

equations

involving

(65)

essential

variables

We define the 4 x 4 matrix p according to (66). p 0 0 0 p 0 0 0 / 9 0 0 0

0 0 0 0

(66)

A combination of (64b) and (61b) results in (67). T2

+ 9y

D

.

2

.

+ dz

d2

7*3 .

D

3

U

(67)

.

Using ty and Ti this equation can be written in the following compact form: d2

(68)

dxr! + dyr2 + dzr3 = £ ^ 2 * Rearrangement leads to (69). d2

-

dyf2 - dzrz = dxf!

(69)

In this equation dxTi is expressed in terms of \P and the undesirable vectors f 2 and ? 3 . In order to obtain an expression for dxTi in terms of $ and T i , and their spatial derivatives with respect to the transversal variables y and z, T2 and I 3 must be rewritten. To this end we use (55) and substitute for dx^. Rearrangement yields f i = [{Ma - MilM^1M12)dy a

+ [MiiMr1 ]fi

+ ( M i 3 - MilM^^M13)dz]

#

t = 2,3.

(70)

Using these equations for F2 and I 3 in (69) and defining the operators

£

2 i =g^~dy -dy

t M 2 2 - M 2 1 M r 1 1 M 1 2 ] dy [ M 2 3 - M 2 i M n 1 M 1 3 ] dz

- 3 , [ M 3 2 - M 3 i M i i 1 M 1 2 ] dy -dz

[ M 3 3 - M s i M ^ M w ] dz

(71)

and La22 = -dy

[MaiMji 1 ] - dz [MaiMJi 1 ]

98

(72)

Theory and Applications of Green's Functions

965

we obtain (73). (73)

CZ1* + CA2T1 = dxT1

This equation has the required properties, and together with (59) builds the desired compact diagonalized form in (74). ra

ra ^-12

ra £ a21 ^-22

fi

fi

(74)

Remarks: • The material matrices constituting C"lf £2i' ^i2> a n ^ ^22 m a y depend on the transversal y and z coordinates, i.e. M j , = M y ( t / , z ) . It is exactly this property that makes this formalism particularly feasible for the analysis of wave propagation in corrugated periodic s t r u c t u r e s . 2 4 - 2 5 • The results presented in this section are valid for two as well as three dimensional problems. The inhomogenity, three dimensionality, and the simple and consistent way for manipulating the piezoelectric equations are among the key features in this section. • Conventionally the constitutive equations are substitute into the governing equations, leading to a system of higher order PDEs. As is obvious from our analysis, it is advantageous not to perform this substitution. Then, the calculations simplify, and we are automatically led to the desired diagonalized forms. To this end, the introduction of rij and N 4 (i — 1,2,3) not only simplifies our calcualtions, but also leads us to our goal. Analogously we may obtain rb A

-ll "l\

Lrb

re re '-21

rb •'-12 '22

L rb

fa

f2

f3

fs

(75a)

r: r> *-:

(75b)

which are diagonalizations of the constitutive and governing equations with respect to y and z, respectively. The expressions for £*- and £?- (i,j = 1,2) can be constructed analogously, simply by inspection. 2.7. Properties

of the diagonalized

forms

We close this section by pointing out major computational properties of the diagonalized forms. To cover the most general case, we allow the material properties to change as an arbitrary function of the transversal variables, say, x and y, associated with the distinguished direction z. Therefore, we will consider the diagonalized equation in (75b), or, equivalently, the simplified representation in (76). CX = dzX

99

(76)

966

A. R.

Baghai-Wadji

Decoupling: For non-piezoelectric matrials (76) decouples into two diagonalized forms: "purely" acoustic (steady state) and a "purely" electrostatic. When assuming isotropic elastic materials with inhomogeneity in only one transversal direction, i.e. x or y, the "purely" acoustic diagonalized form further decouples into two diagonalized forms describing the shear- and sagittal polarized wave propagation. Piezoelectromagnetics: In constructing (76) we assumed that the electric field derives from a scalar electric potential. In Ref. 17 it is shown that (76) can be generalized by considering the electrodynamic equations coupled to the equations of motions. In this case the eigenvector X in (76) contains the components: U\, U2, «3, T5, T4, T3, Ei, E2, H\, and Hi. Et and Hi being, respectively, the components of the electric- and magnetic fields in transversal directions. This formulation remains valid for electromagnetically bi-anisotropic materials. 9 Dispersion Equations: Assume a problem consisting of homogeneous layers. Then partial solutions of the form ePkxX eik*y eXz e~iwt transform (76) into the algebraic form LX = XX. The bar signifies variables in the (kx, fcj^-wavenumber domain. Given the values of kx, ky and the angular frequency u> we obtain eight eigenvalues A'1) and the corresponding eigenvectors, X ; (i = 1, ..,8). A general solution for the vector X can be obtained by superposing the partial solutions:

8

^2 a^X~{i)ejk*xejkyyexWze-j"t.

(77)

i=l

The unknown coefficients a ^ ' have to be determined from the interface and the boundary conditions. Assume that the entire medium, the interface planes included, are free of mechanical and electrical sources. Satisfying homogeneous interface conditions leads to a homogeneous system of equations, AS. = 0. The solvability condition, i.e. det{yl} = 0 leads to the dispersion relationship of the stacked problem. It should be emphasized that with adequate modifications, this approach remains valid if C, e and e, in some or all layers, depend on x and y.9 The wave propagation in shallow and large amplitude gratings can be described elegantly and robustly. 9 Generalized Diagonalized Equations: An important feature of the diagonalization is that it automatically leads to the homogeneous or inhomogeneous interface and boundary conditions. More specifically, assume a multilayered problem with N (in) homogeneous layers, with ith layer extending from Zj to Zj+i. Let z = Zi (i = 1, Af) be the coordinates of the (in)active interfaces. Using Heaviside's function H(z), the material parameters can be written in the form:

P(x,

y,z) = J2 [H(z ~ Zi +i) " H^z ~ *)]?'(*. V)

100

( 78 )

Theory and Applications of Green's Functions

967

pl(x, y) denotes an arbitrary material parameter in i t h layer. Then diagonalization leads to a super equation with N eigenforms (one for each layer) and N + 1 (homogeneous or inhomogeneous) interface conditions. Thereby, the eigenforms and the interface conditions, respectively, appear multiplied by H(z — Zi+i) — H(z — Zj) and S(z — Zi) (i = 1,N). Written symbolically we obtain the form in (79). N

y ^ \H(z — zi+i)

— H(z — Zi) (ith diagonalized equation) +

i=l JV + 1

] P $(z - Zi)(ith

interface condition) = 0

(79)

i=l

The occurence of Heaviside's- and delta functions in (79), and the involved orthogonality conditions allow us to easily identify the eigenforms valid in N layers, and the interface conditions on N + 1 interfaces. Green's Functions: Assume that mechanical and/or electrical sources exist on some or all the interface planes. Furthermore, assume that a few or all the layers are transversally inhomogeneous. The field response to a Dirac delta function excitation is called the Green's function associated with the poblem. In a general piezoelectric medium there are four independent fundamental mechanisms t o excite waves: One electrical point(or line) charge and three mechanical point- (or line) forces directed along the x—, y—, and z axes. The number of the irreducible variables defines the number of Green's functions associated with each of the independent fundamental excitations. In piezoelectric media, assuming quasi-static approximation, the irreducible variables are ip, Ui, U2> W3- This leads to 16 Green's functions ( 4 x 4 dyadic Green's functions). However, not all of these Green's functions are independent. The reciprocity principle dictates certain relationships between the Green's functions. P u t simply, this condition states that by interchanging the positions of the excitation (s: source) and observation (f: field) points we measure the same reaction, field response. The application of this principle leads to the relationships in (80). G«(r/-r,) = G«(r,-r/)

(80a)

Gij(rf

(80b)

- r . ) = Gji(r. - rf)

To understand these equations in the Fourier domain consider the simple case where the source- and field points reside on, say, the z = 0 plane. Denote k|| = (kx,kyY, Eqs.(80) read S«(k||)=S«(-k||)

(81a)

G0-(k||)=^(-k||).

(81b)

Near-field Asymptotic Limits: One of the major advantages of using diagonalized forms is their utilization for determining the asymptotic limits of the Green's functions near the source region in the spatial domain. 9 Green's functions may have singularities. The occurance of these singularities may make the field analysis in terms of surface integral equations a challenge, since generally the near-field asymptotic expansions of the Green's functions are needed. The above eigenform in the wavenumber domain offers an interesting possibility to find these asymptotics. Instead of first constructing the Green's functions and then determining their near-field asymptotics we may alternatively proceed as follows:

101

968

A. R.

Baghai-Wadji

• Calculate the eigenpairs for large values of the wavenumbers (corresponding to the near-field in the spatial domain). • Satisfy the boundary and interface conditions by the resulting eigensolutions.

asymptotic

These steps lead to asymptotic expensions for the Green's functions in the wavenumber domain. Generally these "low frequency" limits for the Green's functions can be transformed into the real space simply by inspection. 9 The resulting functions in the spatial domain represent the asymptotic limits of the Green's functions near-source region. In the next section we investigate these properties in greater detail by studying several examples. (For details see Ref. 9.) 3. A D i s c u s s i o n on Green's Functions In the singular surface integral method Green's functions and/or their spatial derivatives link solutions in the interior of a domain to the values on the domain's bounding surface, and possibly to the sources within the domain as well. The key steps in the application of the singular surface integral method to boundary value problems are the derivation of Green's functions, and the calculation of self-actions. This section is devoted to familiarizing the reader with details regarding these steps. We will focus on four types of problems. • Electrostatic problems in semi-infinite media: 2D electrostatic problems in anisotropic media with a j u m p discontinuity in material parameters along a plane surface. This type of problem is interesting for the following reasons: 1. The underlying algebraic manipulations are tractable and the calculations can be carried out entirely in analytical form; this is useful for gaining physical insight into the problems. 2. The results can be directly implemented to solve a variety of modern engineering problems. 3. Finally, and most importantly, we wish to emphasize the following motivation: dealing with dynamic problems, in the ultimate proximity of the source region, static results represent asymptotic limits of solutions for dynamic solutions; many examples will illustrate this fact. We will employ this property for calculating self-actions arising in BEM. In fact, it turns out that self-actions are static in nature. This property leads to a technique with a promising applicability in practice. Important features of this technique will be shown by comparing the static results with those obtained from asymptotic limits of the scalar wave equation. It should be mentioned that only in connection with vector wave equations do the whole aspect of the underlying relations become clear. • Acousto-electric problems in infinite media: we will continue by considering the acousto-electric dynamic equations in the simplest possible form. It turns out that the calculations here can also be performed entirely in analytical form. This makes possible the investigation of the asymptotic nature of solutions in the ultimate proximity of the source points, in analytical form. The close relation with static solutions will be demonstrated. • Elastic problems in infinite media: the third type of problem involves the dynamic equations of motion in purely elastic isotropic media, Refs. 24 and 25. The isotropy assumption leads to Green's functions in analytical form with the above mentioned advantages.

102

Theory and Applications of Green's Functions

969

• Acousto-electric problems in semi-infinite media: Examples considering piezoelectric half-spaces conclude our discussion. Here also we will start with the corresponding diagonalization equation. Having determined the resulting four eigenvalues and the corresponding eigenvectors, along with our results from the section on electrostatic problems in semi-infinite media, we will be in a position to solve the following semi-space problems: 1. Free space (z > 0)/piezo-electric semi-space (z < 0)-configuration. A line charge and a line force embedded in the piezo-electric substrate will excite the medium. 2. Free space (z > 0)/piezo-electric semi-space (z < 0). A line charge in the free space will act as the source. 3. Piezo-electric semi-space (z > 0)/piezo-electric semi-space (z < 0). A line charge and a line force located in the upper half-space will excite the media. 4. Piezo-electric semi-space (z > 0)/piezo-electric semi-space (z < 0). A line charge and a line force embedded in the lower semi-space will excite the media. Although we will restrict ourselves to 2D problems in this chapter , the solution schemes are also applicable to 3D problems, see chapters two and three in Ref. 9. Furthermore, periodic boundary value problems, and the derivation of the associated periodic Green's functions are briefly discussed in this section. (Regarding the calculation of the self-actions in these problems the reader is referred t o Ref. 9.) 3 . 1 . Green's functions continuity of material

in anisotropic parameters

dielectric

media

with a jump

dis-

Statement of the problem: We consider the following problem which is illustrated in Fig.(l). The region z > 0 is occupied by an anisotropic dielectric which is specified by a symmetric, positive definite matrix ef-u\ Region z < 0 is filled with a dielectric being characterized by e}1'. The superscripts " u " and " 1 " refer to the upper and lower medium relative to the (z = 0)-plane, respectively. In the upper medium we assume that a line charge with co-ordinates x = a and z = c excites the system under consideration. Thus for the source function p(x, z) in our problem we can write p(x, z) = 5(x — a)S(z — c). Our goal is the calculation of the resulting potential function in the entire (x, z)-plane. In mathematical terms, we are interested in the solution of a potential problem subject to boundary conditions at infinity, and to certain interface conditions, with a delta-function "source." The resulting potential distribution will be called the Green's function associated with our boundary value problem. Solution: Technically it is useful to subdivide the (x, 2)-plane into three regions; z > c (region I), 0 < z < c (region II), and z < 0 (region III), Fig.(2). In the following we will construct solutions in each region which satisfy homogeneous differential equations. The unknown coefficients involved will then be determined by imposing the boundary and interface conditions. In this construction, eigenvalues and the corresponding eigenvectors associated with the underlying differential operator will play a central role. 3.1.1.

Diagonalization

For non-piezoelectric, homogeneous, anisotropic, and source free dielectrics diagonalized equation (75b) simplifies to the equation in (82).

103

970

A. R.

Baghai-Wadji

e (u)

a line charge

f C

7 i k

|

X d

(1)

JB

Fig. 1. Geometry of interest.

_e (u)

region I

aline charge

f _e (u)

region II

.

z

C

i

|

X a _e (1)

region III

Fig. 2. Subdivision of the (x, z)-plane into three regions; z > c (region I), 0 < z < c (region II), and z < 0 (region III).

104

Theory and Applications £13 9 £33 9x

££.

2

d

£33 8x'J

L.

\

£33

_£ia^. £33 9x

'

\

/

(

V3 "\ -

U ,

)~dz(

d

(

of Green's Functions

971

(82)

Here, we have used the symmetry property of £, and assumed a two-dimensional analysis by requiring | - E 0 . In addition we used e\> for £116:33 — £i3 2 . The form in (82) is well-structured: it is a diagonalized equation with only those field variables which are relevant to the interface conditions. We substitute for

kxeXz. Our diagonalized equation transforms into the following algebraic eigen value equation £33J

I

I —^k \

2

£33

£33

(83)

-z&jk £33

For the eigenvalue A we obtain the two solutions in (84) £33

£33

with the corresponding eigenvectors given in (85).

X {k)

~ " { eP)k\)

*+<*>" ( - * i | * | )

(85)

Superposition%ads to the following result for (ip, D3)*:

(^,)- a " > w (" 1 w) e , - + " m w (-ii*i)* i *'

m

Remark: The reader may say that "layered" boundary value problems (specified by interfaces z = zW = const) represent a small subclass of boundary value problems, and that, in practice, the boundary shapes are much more complicated, and thus the above-described concepts can no longer be applied. Our answer is that in the case of boundary shapes other t h a n planes, the underlying singular integral equations involve, in the majority of cases, infinite-domain Green's functions (and possibly their spatial derivative). Due to the fact that infinite domains can be composed from two semi-spaces, we can apply the above concept. Furthermore, it should be noted that many engineering problems can be modeled by a combination of layered structures, and subdomains with fairly complicated boundary shapes. In these cases, the Green's functions used are field solutions in layered structures sandwiched between two semi-spaces with proper material constitution. These kinds of Green's functions can easily be constructed by the theory developed here. 3.2.

Boundary

conditions

The boundary conditions on an interface z = z^ 9

= const are as follows:

In Ref. 9 these ideas are generalized and it is shown there that this concept applies with the same simplicity to fields in inhomogeneous media (eij(x,z)).

105

972 A. R. Baghai-Wadji (i) the electric potential is a continuous function. (ii) the normal component of D has a jump discontinuity equal to the charge density function p(x) in this plane. Fourier transforming the boundary and interface conditions, and solving for the involved unknown coefficients oq (k), a.^ (k), a\2'(k) and ctjjjik), in regions I, II, and III we obtain closed-form expressions for n{x, z\k) and
U?-$r%^k\y&'-*A

GAX m -J-J. G (a! z| )

'

' * - 2 e M|*|^W + e W e xe

+e

J

j[-(x-a)+-jK{z-c)]k '33

(87)

e

33;

xe

1

1

(88)

("ft" 2 —fo c )l f c l

Gm(*,z|fc) = - r a (nrrje^ e p + £ p II

«ss

e

J'[-(x-a) + (-^ Z —^yc)]fc

Ss

<33

(89)

We find that Gi(x, z\k) and Gu(x, z\k) have the same analytical form, except for the second exponential terms, i.e., exp(—£p / e ^ (z — c)\k\) and exp(ep / e ^ (z — c)|fc|), which seem t o be different. However, the validity range of Gi(x, z\k) is z > c and thus the equality z — c = \z — c\ follows. We can therefore write the following equation for the second exponential term in Gi(x, z\k):

.(») —fo-(z~ c )l fc l e *W

e(«) —fe-l*-<=ll*l

=e

'as'

(90)

Gu(x, z\k) is valid in the range 0 < z < c and thus we have z — c = — \z — c\ in this region. Consequently, we can write the following for the second exponential term in Gu(x, z\k):

106

Theory and Applications of Green's Functions -c)|fc| e 33

973

-c||fc|

= e

(91)

°33

Thus, by introducing \z—c\, we cannot distinguish between the analytical expressions for Gi(x, z\k) and GJI(X, z\k). This is not surprising, because the introduction of the plane z = c and thus the subdivision of the upper semi-space into regions J and 77 was merely conceptual, and was not based on a physical necessity. Regions / and II are both specified by e ^ and together they build a semi-space into which a line charge has been embedded. In the following we will write G^{x,z\k) in order to refer to Gi(x, z\k) as well as to Gu(x, z\k). The superscript (u) denotes that the validity range of G^u\x, z\k) is restricted to the "upper" half-plane (z > 0). Similarly, as the validity range of Giu(x,z\k) is the lower half-plane (z < 0), we write G^(x,z\k) for Giu(x,z\k). By adding to the Green's function a second superscript "u" or "1", we can make clear on which side of the interface plane (z = 0) the line charge is located, "u" also refers to the upper half-space here, while "1" signifies the lower one. According to this convention, in the present case we can write G^u'u\x,z\k) and G^'u\x,z\k). uu G( ' '(x,z\k) is the electric potential in the upper half-plane as the response to a line charge which is located in the upper half-plane. G"'u>(x, z\k) is the electric potential in the lower half-plane as the response to a line charge which is located in the upper half-plane. So far we have used the constants a and c as the co-ordinates of the line charge. The choice of the "constants" a and c makes it possible to consider the position of the line charge and consequently the location of the upper interface plane to be fixed. However, having already constructed the formulae for the Green's functions, we can perform the substitutions a -> x' and c —> z' in order to emphasize that the derived formulae are valid for any choice of x' and z' for a line charge with z' > 0. Performing these substitutions, we now extend the list of arguments of Green's functions from (x, z\k) to (x, z\x', z'\k) in order to emphasizing the dependency of Green's functions on the co-ordinates of the line charge:

G

(*.*l f l ! . a ! l*)- 2 e W| f c |^W + e » e xe

,, , , , G^\x,z\x',z'\k)=

'ss

1 l (u)

( !

+ e

J (92)

1 (-&*—fey2')!*! j[-(*-*')+(4fy*--JV')]* 4 ? e 4 7 4 7 (93) ) ^ 1

Discussion: Non-oscillatory exponential terms involved in the expression for £(".«). We first consider the exponential function: exp(—£p /e^ (z + z')\k\). The positive-definiteness of e implies that £33 and Ep are positive. Furthermore, we have z 4- z' > 0, because the conditions z > 0 and z' > 0 hold, and thus the equality z + z' = \z + z'\ is valid. Consequently, this exponential function decays

107

974

A. R.

Baghai-Wadji

for any value of z and z', chosen from the definition range, and thus we can write for it the form: exp(—Sp /e 3 g \z + z'\\k\). Our next concern is the exponential function: e x p ( — S p / e ^ \z — z'\\k\). The appearance of the magnitude sign in \z — z'\ ensures that this exponential function decays for any values of z and z'. Non-oscillatory exponential function appearing in (?('•"); that is: exp (sp /e^\z— £p /e^ z')\k\). By definition we have here the equations z — —\z\ and z' = \z'\. (Remember that the definition range of G^l'u^ is the lower half-space, and t h a t the line charge is located in t h e upper half-space.) Thus this term becomes exp(—(s p /egg \z\ + £p /S33 \z'\)\k\), which is an exponentially decaying function. For a line charge source located in the lower half-plane we denote the resulting potentials in the upper and lower half-planes, respectively, by (?("'') and G^l,l\ The reader can verify that (?(">') and G^l'V> have the forms:

G<^(s,z|^z'|A) = - ? - ^ - ? j T _ <_">+el*

c

(94)

MID,

1'

',M

1

G Hx zlx zlk)

1 ( 4 ° - ^

e

-l1^11'1

> > ^w\[t^ j[-(x-x')

Xe

+

-$\*-*'\w\

+e

)

-tfr(z-z')]k

*33

(95)

Arranging the above four Green's functions in matrix from, we can define a matrix Green's function G as / G^u\x,z\x',z'\k) a(x,z\x',z'\k)=\

\ G^u\x,z\x',z'\k)

G^l\x.z\x',z'\k) \ .

G^(x,z\x',z'\k)

(96)

J

3.2.1. Properties of G_ The multiplicative factor l/\k\, which is an even function of k, appears in all elements G^a'b^ with a = u,l and b = u,l. Note that ±|fc| are the eigenvalues of the Laplace operator in isotropic media. The non-oscillatory exponential functions involved depend on \k\, and thus are even functions in k. In order t o carry out further properties of G^a'b\ we consider their integration over k to transform them into real-spacei* ''•Strictly speaking, the analysis in the remaining of this subsection and in the following two subsections is not mathematically rigorous. A more careful analysis based on the theory of distributions would be outside the scope of this elementary treatment. The final results are, however, correct and extensively tested.

108

Theory and Applications —e

G^bHx,z\x',z')=\im\

975

oo

f ^G^b\x,z\x',z'\k) e—>0 I J

of Green's Functions

~G^b\x,z\x',z'\k)\

+ [

2f

J

Z7T

J

e

—oo

oo

= -f-^G^b\x,z\x',z'\k)

(97)

—oo

Because of the first two of the above properties, we recognize that only the real parts of the oscillatory exponential functions contribute t o the integrals. Then, by writing

we have

1

G^u\x,z\x',z')=

~(«) _ J O + o o

,.£f.

1

^^rffcfe

-'-E-r\z+z'\k

'»

e («) xcos|(x-a:')--^-(z-z,)l&

£ 33

+

,(") +°° 1 —^iylz—z'tA £ («) ^4-dk-e 'M c o s i ^ - a ; ' ) . 13 ( Z _ / ) | A ; 2weP o -G33 1

Gil'u\x,z\x',z')

=

, .

... 4-dk-e

^i

4F

(0 («) xcosl(s-s')-(%*-%*')!* s

, n

33

,

e

7r(ep

+~

+£p ) 0

J«0 JO xcosKx - x') - (e-f-)Z 33

(100)

33

1

£

(99)

e

33

109

1 -(-&yl 2 l+-frl z 'l)fc K

£

-f)Z')\k

(101)

976

A. R.

Baghai-Wadji

(0 ~{z - z')\k

xcos|(a: - a;')

-33

l

4 -

- ^ | 2 " Z ' fc

1

^

+—'-^-f-dkye 2 ^-F 0 u *

'as'

JO £i ' cosKz-zO-^-fz-*')!* c- ^ 33

(102)

+oo

where the symbol -f- has t o be understood in the sense that o oo

+oo + oo /• -A-dA; • • • = l i m / dk • • •.

o

^-W

From these representations the reader can immediately deduce further facts and properties of the Green's functions: The above integrals do not exist (even in the Cauchy sense ), as we will soon see. This is a consequence of assuming a single (isolated) line source for our problem. In the subsequent discussion it is shown that the above integrals allow a meaningful interpretation if, and only if, we consider a collection of line charges which is charge neutral. Considering a group of N lines with charge magnitudes per length (in y—direction) being denoted by <&, we obtain for the charge neutrality condition N

J

J dxdzp(x, z) = J f dxdz V J qi8(x — Xi)8{z — Zi) =

—oo —oo *

— oo—oo

^=1 N

oo oo

= ]L* / /

dxdzS x x s z

( - i) (

-zi) = J2Qi=°-

( 103 )

Eq.(103) can alternatively be called the balance-law, the conservation law or the regularization condition. Interchanging t h e locations of the source and t h e observation points (a;', z' o x,z), G'"'™) and G^*^ remain unaltered, G{u'u\x',z'\x,z) (l

l

G > \x',z'\x,z)

= G(u'u\x,z\x',z')

(104a)

= GV'l)(x,z\x',z').

(104b)

The substitutions x', z' <-» x, z, however, transform G^' u ) into G ( "' Z) and G*"'^ into G('-") G{l'u)(x', M

z'\x, z) = G(u'l\x,

G (x',z'\x,z)

u

z\x', z')

= G^ \x,z\x',z').

110

(105a) (105b)

Theory and Applications of Green's Functions

977

These two properties result from the validity of the reciprocity property in the boundary value problem under consideration. A formal proof of these facts is omitted and is left to the reader. 3.3. Real-space

Green's

3.3.1. Preparatory

functions

calculations

Let us consider the following table integral oo

e-ak

_ e-/3fc

{dk

COSbk =

k

b2 + /32

i

2 l n 6^W

(1 6)

°

Re[/?] > 0; Re[a] > 0. (Formula 3.951/3 of Ref. 27.) In the special case that a is zero, Eq.(106) becomes c» 1 __ e-?k 1 h2 4- B2 Jdk=-~ cosbk = j-ln Zf .

for

Z

K

Q

(107)

0

We now consider integrals of the following type which arise in the expressions G^a'b\x,z\x',z'\k): f e~0k I = 4-dk—-—cosbk J k

f e~^k = lim / dk——- cosbk = lim 7 £ . e-+o+ J k £->o+

0

(108)

£

The subsequent steps are self-explanatory. 00

f Ic =

00

e~l3k dk—-—cosbk=

00

f 1 - e~Pk f 1 — / dk cosbA; 4- / dk—cosbk

e

e

e

00

00

= — J dk-—^

cos&A: + J dk^^~.

0

(109)

£

Using (107) we can write 1, b2 + (32 f „ cosbk h= — ~ m — r ^2 1- / dk1 b ) k OO

2

2

= - i l n ( 6 + /3 ) + l n | 6 | + y ^ ^ .

(110)

e

Now let us focus on the integral on the right-hand side. By employing the variable transformation bk = t, this integral becomes 00

00

„ cosbk

/

dk

f , cost

-k~ = J dt~ 111

.

(U1

)

978

A. R.

Baghai-Wadji

Then based on the relation 1 , cost

,

f , cost - 1

,

/ dt

(112)

/ dt = - 7 - lnz (|arg{z} | < 7r) we come to the result oo

eb

„ cosbk

/

dk——

,

, ,,,

r

= - 7 - lne - ln|6| -

cost — 1

/ dt

£

,

.

(113)

0

Using this formula, we obtain for It (as given by the second equation in (110)) the following: eb

1 , ,.o. . „ • > * . , , , , h= - i l n ( 6 2 + /32) + ln|6| - 7 - lne - ln|6| -

f f

costt

1

0 eb

= -iln(62 + / 3 2 ) - 7 - l n e - | d t ^ L l i .

(114)

0

At the limit e —>• 0

+

the integral on the right-hand side vanishes and we obtain I = -hn(b2

+ j32) - 7 -

lim lne.

2

(115)

e-»0+

Using the definition equation for / , Eq.(108), we obtain the following formula which plays a central role in our analysis: T e-P" -/- dk——cosbk J 0

1 = - 7 - lim lne - - l n | 6 2 + (52\.

K

e—•()

J,

(116)

By considering the fact that the constituent integrals of the various Green's functions G^a,b\x,z\x',z') are of this type, and collecting together the singular terms, it is not difficult to obtain the expression for the Green's function G^u'u\x.z\x' ,z') in real-space: G{u'u\x,z\x',z')= »

_ ,,(0

£p

ln{[(* i - £p r

1 •*7T£:p 1

4™#>

p-.

'

"•"

7 7 r ( - 7 - lim lne) -(«)

> )

/N

£

- *') " e% ( * - -')]2 + efe(* + z')}2}

1 3 /-,

33

33

g

,/\l2 , f P

/•„

^/M2

W K * - *') - ^ ( z - z')] 2 + lF £ y ( * - ^ O H -

^

4«>

1

(117)

T h i s formula h a s been derived by combining t h e formula (5.2.27), pp.232 w i t h t h e formula (5.2.2), pp.231 from H a n d b o o k of M a t h e m a t i c a l Functions, Abramovics a n d S t e g u n . 2 7 Here 7 , b e i n g equal t o 0.577256649, d e n o t e s t h e Euler c o n s t a n t .

112

Theory and Applications of Green's Functions 979 The expression for G{l'u)(x,z\x',z')

G^\x,z\x>,

can readily be written in the form

l

z>) =

( - 7 - £Hm In.) £_ J "

ir(ep' +£p)

2lT(£p

+ £p

)

£33

£33

(118)

e

£33

33

Remark: We have added the symbol e t o these functions in order t o emphasize the existence of the e-dependent terms in their expressions. As pointed out earlier, by substituting £ ( u ) <-> £ ( ' } , G^'u) (x, z\x', z') transforms into G{l'l)(x,z\x',z')

while G(!'u) (x,z\x',z')

G^Hx,z\x',z')

transforms into G(^'l) (x,z\

* m ( - 7 - Um Inc) £ 7r(eF'+ep) ^-° («) JO _(«) 2 U V ;J + v few MK* *' ) ^ T * %*')] ,._/>) , J 0 / ' >) JO ' >> Z7T^£p

=

+EpJ

1

£33

C33

p(') _ p(«)

^7U^ 1 (I)

*7reP

gp

~

x>)

JO

+ JO ^rl-'l)2} £33

JO

{z

z )f + l

- 7* ~ '

-t-5p

(119)

t33

Fm

ln{[ix

t/iep

x',z').

s33

7i{z + z')]2}

e33

JO JO u v - - x') ~J ~ - -z')f /J + . 1 fer{z ( J )(v z (0» ]n{[(x - % - z')f] e e 33

(120)

33

These forms allow the recognition of further properties of Green's functions. All t h e four Green's functions possess a common constant singular term. Thus we can write

G{a'»\x,z\x',z')

=

} n{eP

+ey)

( - 7 - hm lne) + G^b\x,z\x',z'). £ +0+ -

(121)

This fact is crucial and plays an important role together with t h e charge neutrality condition: We show that for charge-neutral systems (physically realizable systems) the above mentioned singular term vanishes. Consider in t h e upper and lower semi-spaces, respectively, charge distributions p(u\x,z) and p^l\x, z) in such a way that the charge neutrality condition holds 00

00

00

00

/

/ dxdzp(u\x,z)+

J

J dxdzp(l\x,z)

113

= 0.

(122)

980

A. R.

Baghai-Wadji

Based on the linearity of our problem, and on the definition of Green's functions Ge (x,z\x',z') as responses t o a single line charge, we can write the following equations for tp(u\x, z) and tp(l\x,z):

V? (p) (x,z)= /

Jdx'dz'GiP'u^(x,z\x',z')p^(x',z')

—oo—oo oo oo

+ J J dx'dz'G
+C

(123)

(p = u, I.) The functions ip^(x, z) and ^l\x, z) have the following meaning: (u>(x,z) is the electric potential distribution in the upper half-space when both u p( \x,z) and p^l\x,z) excite the medium.
OO

OO

OO OO

x[jf f dx'dz'p(u\x',z')+

f

— OO — O O OO OO

+ / /

from (121) and collect-

J

dx'dz'pM(x',z')]

— OO — OO

dx'dz'G^u)(x,z\x',z')pM(x',z')

— OO — O O OO

OO

+ / / dx'dz'G^'l\x,

z\x', z')pV\x',

z') + C

(124)

(p = u, I.) We see that if, and only if, the charge conservation law Eq.(122) is valid, that the terms carrying (—7 — lim lne) vanish and the above equations make sense. We further recognize the relevance of the singular terms appearing in a common form in the pairs Ge (x, z\x', z') and Ge {x, z\x', z') and in the pairs G[l'u\x,z\x',z')

G{IJ)(X,Z\X',Z').

and

Therefore, under the assumption that the charge neutrality condition holds, we can omit the singular terms and operate with G^a,b\x,z\x',z'). 3.4. Periodic

Green's

3.4.1. Construction tions in real space

functions

of periodic Green's functions

using nonperiodic

Green's func-

We assume a sequence of infinite number of line charges which are located on the plane z = z', Fig. (3). The line charges are assumed to be positioned in a parallel fashion, at a distance P from each other. The charge magnitude per unit length is taken t o be unity. The surrounding medium is an isotropic dielectric with a dielectric constant e. We refer t o t h e strip defined by - P / 2 < x < P/2 as t h e fundamental cell.

114

Theory and Applications of Green's Functions

981

a periodic array of line charges

an isotropic infinite-space characterized by

8

Fig. 3. An infinite number of line charges.

The Green's function associated with a line charge with co-ordinates (x',z') the fundamental cell has the form

G £ ( x , z | z ' , z ' ) = - - r - ( - 7 - lim \ne) - ~ln[(x 47re e->o+ Aire

- x')2 + (z - z')2].

in

(125)

By considering the fact that in physically realizable systems the fundamental cell will contain a charge-neutral system, we omit the singular term to obtain G(x, z\x', z') = ^-— ln[(z - x1)2 + (zAire

z')2].

(126)

We now come back to our line-charge array and superpose the associated potentials to obtain the periodic Green's function GpeT(x,z\x' ,z'), which characterizes the aforementioned line charge array. Using (126), we readily obtain

GpeT(x,z\x',z')=

oo

£ G(x,z\x' n=—oo

I 47T£

-nP,z')

£ ln{[x - (x' - nP)]2 + (zn=—oo

z')2}.

(127)

We see that whenever the Green's function associated with a single line charge (point charge in 3D problems) is available in real space in closed form, it is an easy

115

982

A. R.

Baghai-Wadji

task to construct the corresponding periodic Green's function. Note that in practice the series involved have t o be truncated, by letting the dummy index n run from —N to TV. Numerical calculations indicate that in electrostatic problems, for values of N of the order of 10, we obtain satisfactorily results. 2 8 The construction of GpeT(x,z\x',z') relying on the real-space Green's function G(x, z\x', z') of a single line charge is one of the two alternatives. In the following discussion we will be acquainted with a different way which merely requires the Green's functions in wave number domain. 3.4.2. Construction number domain

of periodic Green's functions

using Green's functions

in wave-

We consider again the line array from the previous section. In order to construct the associated periodic Green's function, we consider first the Green's function in the wave number domain of a line charge located in the fundamental cell. The latter function is G(x,z\x',z'\k)

= -l-I-<J<*-*'>fc c -l*-*'ll*l.

(128)

Using this equation, we easily obtain the Green's function associated with the n t h line in the wavenumber domain, simply by changing x' to x' — nP, that is G(X,Z\X'

-nP,z'\k)

= Ll-e3[x-(x'-nP))ke-\z-z'\\k\, 2iZ ]rC|

(129)

Summation over n, ranging from —oo to oo, yields the wave number domain representation of the periodic Green's function we are looking for: oo V

Gper(x,z\x',z'\k)=

±±-eJ[x-(*'-nP)]ke-\z-z'\\k\_

(13Q)

^—' 2e \k\ n=—oo

' '

Integration over k yields the Green's function in real space oo

Gpel(x,z\x',z')

Jt

Gpel{x,z\x',z'\k)

= / — _ ™ 27T

f _ 9-rr

J

= 7—

V^ Z ^ Or |£.| n~—oo

}_J_e3[x-{x'-nP)]kp-\z-z'\\k\

— — e3(x-x')k

-\z-z'\\k\

y^

_ J 00 2 7 r2e|fc| 0 0

'

^

'

gjnPfc

Q31N

•

\

i

72 = — O O

By using the relation oo

oo

_L J2 e~^Pk = ± £ n=—oo

n=—oo

where Kn is defined by Kn — n2ir/P we obtain

116

S(k-Kn)

(132)

Theory and Applications of Green's Functions

G(x,z\x',z')=

j d k ~ S ' - ' — °° 1

= p

>ke^-*

Nfcl-i J2

' '

983

S k K

( ~ n)

n=—oo

°°

E

G(x,z\x',z'\Kn).

(133)

n=—oo

Remark: Once the Green's function in wavenumber domain, that is G(x,z \x',z'\k), is available, it is an easy task t o construct its periodic counterpart in spatial domain: we essentially have to sample G(x, z\x', z'\k) at discrete points k = K„ and to add the sampled data. Remember that the derivation of G(x, z\x',z'\k) is an algebraic calculation and basically demands the eigenvalues and eigenvectors associated with the partial differential equations under consideration. The above series representation is a convenient form for further manipulations involved in BEM-applications. This results from the facts that the variables x and the z are separated in the expression of Gper(x,z\x', z'), and t h a t the functions involved are exponential in nature. These properties make differentiation and integration easy tasks. We know t h a t these properties also hold true if we consider the Fourier representation of G(x, z\x', z'), associated with a single line charge, i.e. G(x,z\x',z')=

f —G(x,z\x',z'\k).

(134)

-oo27T

The reader may ask what is peculiar about the series representation. The answer can be found in the last tliree chapters in Ref. 9, where we are concerned with selfaction calculations. It is worth mentioning that the above-mentioned properties get lost in the spatial domain: the Green's functions in spatial domain are not generally "variableseparated" , and their functional structures are fairly complicated in the majority of cases. In one particular case the transformation of non-periodic Green's functions into real space becomes very easy. This is the case when we transform into real space the asymptotic of a non-periodic Green's function in wavenumber for k ^> 1. As mentioned above, in BEM applications the self-action calculation is essential. By definition, self-action determination demands that the observation point coincides with the source point (x —• x' and z —» z'). For reasons of simplicity, let us assume that the source point resides at the origin of the co-ordinate system; thus we can assume that x,z -C 1. Then, in order t o calculate the self-action, we have t o investigate the field behavior in the neighborhood of the origin of the co-ordinate system. For this purpose we recall the property that the Fourier transformation projects the vicinity of the origin of the (x, z)-plane into the far zone in the /c-plane. Thus, self-action calculation requires the asymptotic of Green's functions for k S> 1. The last section in this chapter is devoted to this technique. Calculations will be performed entirely in analytical form, and thus the reader will be provided with many useful details in connection with self-action analysis. Phased Periodic Green's Functions: For completeness it might be mentioned that in a variety of applications it is necessary to construct Green's functions associated with periodic phased-line arrays. The latter are periodically arranged, localized sources, that are driven in such a way that the potential of n t h line charge is given by exp(.;'A:oa;n). Here xn is the a;-co-ordinate of the n t h line charge and ko is assumed to vary from —w/P to ir/P. The Green's functions associated with phased arrays are closely connected with the aforementioned "ordinary" periodic Green's functions,

117

984

A. R.

Baghai-Wadji

1ioe spate

X a piezoelectric semi-space supporting SHW

-

*

•

•

a line charge + a line force Fig. 4. A piezoelectric semi-space with a line charge and a coinciding line force located at point (x1, z') beneath the surface plane. Above the surface is free space.

and from a theoretical point of view, provide no significant contribution to BEM theory. For this reason we will not be explicitly concerned with phased periodic Green's functions in this work. For details the interested reader may refer to Refs. 9 and 11.

3.5. Infinite-domain wave problems

Green's functions

associated with

Bleustein-Gulyaev

The treatment of Green's functions in this section provides the reader with further information concerning the construction of elemental solutions of partial differential equations. Statement of the Problem: We consider a piezoelectric semi-space with a line charge and a coinciding line force located at point (x', z') beneath the surface plane. Above the surface is free space, Fig. (4). It is known that under certain circumstances «i and U3 decouple from u^ and if, and it is possible to excite surface waves («2, f) which propagate along the interface z = 0. This type of waves are called Bleustein-Gulyaev Waves, Refs. 29 and 30. 3.5.1. form

Construction

of infinite-domain

Green's functions

using 2D Fourier

trans-

The analysis in this section is devoted to the construction of the infinite domain Green's functions. For this purpose we assume a line charge and a line force be located at the point (a/, z'), and find the resulting elastic displacement component M2 and the electrical potential ip, associated with an unbounded piezoelectric medium. The simplest possible equations for describing this type of motion are the following:

118

Theory and Applications of Green's Functions 985

d2 { p

d2 + Ci4

-W

d^

2

d ( e ^

d2 + C

d2

)U2

+ ( e i 5

"^

2

2

d d +e ^ ) u 2 - ( e n - ^

^

d2 + e i 5

5^ =°

(135a)

2

d + en^)
= 0

(135b)

Here, only one single piezoelectric constant, that is eis, couples the Newton equation of motion for 1*2 and the Laplace equation for tp. In the following we will assume a harmonic time dependence according to e~ J "'', define a transversal bulk velocity ct (c2 = Cu/p), and use the Laplace operator A = d2/dx2 + d2/dz2. In this section we have the problem of demonstrating a way for directly constructing infinite domain Green's functions, and of making the reader familiar with k ;» 1—asymptotics of dynamic Green's functions, and their relations t o static solutions. Whenever we are interested in 2D infinite domain Green's functions, it is preferable to use a 2D Fourier transform. This is the way the calculations are carried out here. The definition equation for the infinite domain Green's functions Gu, G21, G\2 and G22 associated with Eqs.(135) is

We use a 2D Fourier representation for the Green's functions in the form OO

Gmn(x,Z\x',z')=

OO ,1U

AU

J J ^^gmn(ki,kzyk^~*Vfc»<*-*'>

-00-00

™

(137)

^

(m,n = 1,2). Transforming (136) into the Fourier domain we obtain

pu? - c44(k2 + k2) -e15(k2 + k2)

- e15(k2 + k2) \fgu en(k2 + k2) ){g21

012 \ _ ( 1 0 \ G22)-\Q I)'

(138)

Using the notation k\\ = kf + k2 and solving for Qmn, we obtain Gu G12 \ G21 G22 )

=

J_ ( sukl det \ e15k\

e i5*f \ / 1 0 poj2 - CiAk\ / I 0 1

(139)

where det stands for the determinant of the far left matrix in (138), and is thus det = (snk2)(puj2 — C^k2), where we have defined the stiffened elastic constant C44 using the equation: C44 = C44 + e\5/e\\. From this we define the transverse velocity ct thus: c2 = C44/P, as the characteristic bulk velocity in a stiffened elastic medium specified by C44 and the mass density p. Note that the term e^k2 represents the Laplace operator in a dielectric specified by e n , while the term pus2 — C44&M corresponds to the Helmholz operator in a stiffened elastic medium characterized by C44 and p. From (139) we then obtain

119

986

A. R.

Baghai-Wadji

&i(*ll)=

^

2

,2

(140a)

:i5/y,2

g21(ftii)=g12(feii)=

fea(*i)=rJgr+

(nob)

(e 15/ )2 2 y ,2-

<140c)

We notice that the functions Qmn are built up from the following two fundamental types: r

i(fcll)=

2 V

a n d

1.2

^ l l ) = THfl

(141)

Before we proceed with the transformation of these functions into real space, we will discuss the asymptotic properties of 0 n , Q21 Q12 a n d 022 for k\\ ~> 1. These asymptotics are of importance because they describe the behavior of the fields in the immediate vicinity of the line sources, and are thus of major importance in self-action calculations. The appearance of only one characteristic velocity, that is Zt, simplifies the calculation, and we obtain

(142a)

lim 0 i i ~ - = - T 2 - - I r - r - j L 2 fc

||»l

O44 «||

O44 £llK||

lim g21 = lim g12 ~ - ^ ^ = -^r-^rs fc||»l

*||-K»

lim fe - -5-4 *ii»i

3.5.2. Transformation

k

C44

(ei5

e n kf,

-/

\\

£ll)2

C44

C44^H«|

^ = £±*

K

(U2h) (142c)

Cuenki

into real space

We have found out that the functions 7i(ky) and 72(A;||) (Eqs.(141)) are building blocks of Green's functions Qn, g21, 012 and 022- Thus, in order to construct these functions in real space, it suffices to calculate T\(x, z\x',z') and T2(x,z\x',z') as their inverse transforms. In Ref. 9 it is shown that we have:

T^xMx',y')

= -3-r±-H™(±Rq) 4 G44

T2(x,y\x',y')

(143a) c

= -—L-bxRH + ^ - { l n 2 - 7 -

lim lnc}

(143b)

Remembering the charge neutrality condition, the singular term on the righthand side can be omitted, and we are left with T2(x,y\x',y')

= --^—lnR]].

120

(144)

Theory and Applications of Green's Functions Having calculated Tx(x, z\x', z') and T2(x, z\x',z'), Green's function matrix in the following form: / Sn{x,y\x',y')

Q12{x,y\x',y')

\ S2i(x,y\x',y')

G22(x,y\x',y') )

987

we can set up the desired

\

(145)

_(

-^^(fi?,,)

-i^H^ifR^

3.6. Infinite-domain Green's functions tion in purely elastic media 3.6.1. form

Construction

of infinite-domain

Preparatory considerations: integrals of the form

i>(xux3)=

Green's functions

with scalar

wave

equa-

using ID Fourier

trans-

In BEM applications we are dealing with surface

/ dx^n's

+

associated

\

dJ

X^.4)

J dx^^^hiA^

(146)

n\ and 713 denote, respectively, unit normal vectors parallel to the x\- and x3axis, and G(a;i,ar3|a^,a^) is defined by

G(X1,XM,4)

=_/

-iL-j

(147)

with a t (&) = (&2 — (u,/ct)2)1^2Because our interest is the investigation of the results for k 3> 1, we have chosen this branch of the square root for at(k). ct is a characteristic transverse velocity and u> is the angular frequency. We consider the spectral component ejk(xi-x[)e-at(k)\x3-x'3\

-2ut(k) in the integral representation of G(xi,x3\x\, x'3). Apparently the symmetry with respect to (xi — x\) and (£3 — x'3) has been broken. However, adding together all the "^-components" we obtain in real space a function which is invariable with respect to an interchange of (xi — x\) and (2:3 — x'3). The validity of this statement is obvious in the present cases: as we know, the integral in (147) is the Fourier representation of the Hankel function HQ

" * " < ! * . > - / 2TT

121

'(f-R\\)

-2at{k)

988

A. R.

Baghai-Wadji

which is a function of R\\ (Euclidian distance between (a;i,a;3) and (x^x^)), therefore symmetric in (xi — x^) and (2:3 — x'3). Thus we can write

G(x1,x3\x,1,x3)

= H^(^Ri)=

[

-I

e>k^-Xl~x'^e~at^k^Xi~x^ -2at(k)

dk 2K dk

and is

e-

Q

'(fc)lxi-3:ileJ*:(x3-x3)

27r

-2at(k)

'

(148)

This fact is important in the further development of our ideas in the BEM applications. 3.7. Near-field asymptotic limits of Green's function derivative with respect to x\ and x3

G and of its

spatial

There are two alternative ways to calculate the near-field asymptotic limits of G(x\,x3\x\,x3) and of its spatial derivatives. • standard procedure: This is the way we performed our calculations in the proceeding section. The method is based on the Green's function G(xi,x3\x[, x'3) in real space. Having constructed G(xi,x3\x'1,x3), we can find the asymptotics of G, dG/dx[ and dG/dx'3 directly at the limit R\\ 1 3. extrapolate the resulting function in the entire range of k 4. calculate the inverse Fourier transformation of the extrapolated function. The resulting function represents the near field asymptotic of the Green's function in real space. As we will immediately see, all these steps are extraordinarily simple and can be performed in a straightforward manner. In the following we will perform these steps by concentrating on scalar waves. In the next three subsections we will be concerned with the analytical details of the above-mentioned steps by considering the functions G, dG/dx\ and dG/dx'3. 3.8. Near-field

behavior

of Green's function

G

Our goal in this section is the investigation of the near-field behavior (i?y -C 1) of G{x-i, x3 \x\, s 3 ) by considering the asymptotic limits of the Green's functions in the wave number domain for k 3> 1. For this purpose consider the integral representation of G{xx,2:3la/j,x'3) as given in (147), and perform successively the above mentioned steps. We find that at(k) behaves like |fc| for k » 1, that is at(k) ~ |fc|. Consequently we can write ejk(x1-x'l)

x x

-at(k)\xs-x'3\

eJk(

-2at(h)

l- i)e-\k\\x3-x
-2|fc|

Let us now construct a function S(xi,x3\x'1,x3) in real space by using the function on the right-hand side of the above O (order)-equation, that is

122

Theory and Applications of Green's Functions 989 x

1 +00

S(x1,x3\x[,x'3)

ejk{

1-x'l)

e -|fc||Z3-

x

3l

= --+dk

.

(149)

The imaginary part of this integrand is an odd function of k and thus its contribution t o the integral vanishes. With Tle{ejk{xi-X'l)}

= cosk{xl

- x\) = cos^llx! - x'x\

we then obtain S(x1,x3\x[,x'3)

= - — ^dk

!

ji

.

(150)

We compare this integral with the integral in (147): the variable k appears in the oscillatory part and in the decaying part in Eq.(150) as it stands, and, unlike the case in (147), not as a function of k. Further notice the polynomial appearance of k in the denominator in (150), which is much simpler than k in at(k) as is the case in (147). Recalling the result +00

e-0k

-fdk——cosbk Q

1

lira lne - - l n | 6 2 + /3 2 |

= -7 -

k

e—fO"*"

(151)

2

we can write

5(a;i,a;3|a;' 1 ,4)= ~ ^ ~ { - 7 -

" m lne - - l n [ ( x ! - x[)2 + (x3 - x'3)2]}

This is the near-field representation for the Hankel function HQ (fR^) the near-field representation of our Green's function G(xj,x3\x'1, x'z). Gix^x^x'^x's)

_hxR,. ~

Z7T

+

and thus

( 7 + i i m in€). 2.TT

(153)

e->-0+

In the light of the above derivation it is instructive to summarize the relevant steps: • Consider the representation: G(xi, x3 \x\ ,x'3) o G(xi, x3 \x[, x'3 \k). • Find the asymptotic limit of G{x-l,x3\x'1,x'3\k) S(xi,x3\x'1,x'3\k).

for k > 1: G{x1,x3\x'1,x'2i\k)

~

• Extrapolate S(x1,x3\x'1,x'3\k) over the whole definition range of k, that is (-00,00): which means letting S(x1,x3\x'1,x3\k) be valid for any value of k. • Calculate the inverse transform of

S(x1,x3\x'1,x3)

S(xi,x3\x'1,x'3\k)

°° dk = / -

123

m

2-K

—S(x1,xs\x'ux'3\k).

990

A. R.

Baghai-Wadji

• The function S(x\x')

is the near field representation of

G(x1,x3\x'1,x3)

3.9. Near-field

behavior

3.9.1. Real-space

analysis

"

S(x1,x3\x'1,x'3).

of the ^-derivative

Using the relation (d/dx)H^\x)

of Green's

= -H^ix)

flgfri,xalx'^x'z)

~ ~ *~c

functions

we have

w (Xl - x\) 3

^

G(x\x')

fl„

w

(1)

Fl

{ R

(154)

7^

At the limit R«
frl^Rl)

'l«1

Then (154) gives dG(x1,x3\x'1,x3)

fin

dx\

< 1

a;i - x[

~

*~RJP'

(155)

This technique requires the Green's function G(xi,x3\x'1,x'3) in real space to find the asymptotics of its spatial derivatives for R •< 1. In the following we show an alternative procedure with a promising applicability range. 3.9.2. Wavenumver

domain

analysis

By using Fourier integral representation of G(xi,x3\x'l,x'3) dG(x1,x3\x'1,x'3)_ dx\

we can write

dkeM^-Oe-0*™**-*'^ -2at(k)

d °? ~ 'dx~{J002ir

jke:>kl-x'i~x'^e'~at<'k^X3~x'^ 2Mk)

°° dk = ! * ;

(156)

Again with at(k) ~ \k\ for k ~^> 1 we can determine the asymptotic of the above integrand which is AUf,jk(x/,—x/,)

•7fee

e

-at(k)\x3-x'3\

_-r.

JJL.eJH<-x'1)e-\k\\x3-x'3\ 2at(k) 2\k\ Denoting this limit by W(a;i,a;3|a;i,a^|fc) we can write Wix^x^x'^x'^

^

°° dk J

—W(x1,x3\x'1,x'3\k)

= J dk-^-reSM-'ih-Wte-^.

124

(157)

Theory and Applications of Green's Functions 991 In contrast to the previous case the imaginary part of ePk^x^~x^> here contributes to the integral and we obtain 1 °° / Wix^x^x'x'z) = - — fdksiakix! - x'^e'^3-^.

(158)

27T 0

We use the table integral °° Jdxe

1 px

sin(qx

j (QCOS^

+ A) = —2

+ psinA)

(159)

(p > 0.) (Formula 3.893/1 of Ref. 27.) which in the special case A = 0 reads oo

a

fdxe-pxsm(qx) o

=

02

0. P +Q2

(160)

Employing this result we obtain (161) which gives the near-field behavior of dG_ dx[

dGjdx'x

i?|| » 1 ~

_ 1 xi - x\ 2?r ijy 2

(162)

This result proves that the processes • spatial domain differentiation with respect to x'x • wave number domain integration over k • spatial domain asymptotic order-calculation (R^ -C 1) and • wave number domain asymptotic order-calculation (k\\ S> 1) commute in the following way: Asymp

. d

°? dk _,.

, , ,,,.,

-Is 7" i^-*"*»i 3.10. Asymptotic

behavior

of dG/dx'3

Consider the following self-explanatory calculations in the wave number domain:

125

992

A. R.

Baghai-Wadji

dG(x1,x3\x'1,x'3)_ dx'3

d °? d f c e J f c ^ i - < ) e - t t ' W N - ^ l "d^J^Tr -2at(k) 1

OO

= - — t a g n ( x 3 - 4 ) / d * c o s * | a ; i - a;' | e -«t(*)|*s-* s l 2lT 0 1 °° ~ - — sign(z 3 - x'3)Jdkcosk\xi - a^le-*1*3-^! 2-K

(164)

0

Using the table integral oo Sdxx^e-f'coBbx

an = { - V T W

¥

a E -

(i65)

(Re/3 > 0; b > 0) in the special case n = 0, that is oo

a

JdxcoBbxe-P" o

= -^SJ b2 + P2

(166)

we obtain 0G(a;i,a:3|a:i,a:'3) 1 12:3-2:3 ~ - ^2-K s i g ns ( av": 3 - 2:i ;3)( - x\f + {x - 4 ) 2 0*3 Xl 3 1 2:3—2:3 ~ _ 2 ^ r iJ,, 2

3.11.

Calculation

of self-action

in

(167)

BEM

In certain BEM calculations we are concerned with integrals of types TI \ I(x1,x3)=n1 J(x1,x3)

t , ,dG{x1,x3\j^1^ dx3 i—J-J-+ = -n3

, aG(a:i,2;3|2:i,4) / dx\

> (168a) (168b)

which for coinciding observation a n d source points deserve special a t t e n t i o n . 3.11.1. Calculation

of I-type

integrals

Substituting x'3 = x3 + u and x\ = x\ + e the following relations are valid: 2:3 — x'3 = — u

xi — x\ = —e

In the ultimate proximity of the observation point (2:1,2:3) we can employ the asymptotic expansion of dGjdx\ from the previous subsection. Thus we can write

126

Theory and Applications of Green's Functions 993 23-A3/2

,dG(x1,x3\x'1,x'z) c

dx[

X3+A3/2 X3-A3/2

1 '27T

f J

, , si - x\ ^ ( x . - x ^ + ixz-xtf

X3+A3/2 -A3/2

= — 2ir

/ J

A3/2

du-x 7; = — / e2 + u2 2TT J

A3/2

du-r. ,. e2 + u2

(169)

-A3/2

By substituting u = ev and thus du = edv (169) becomes A3/2c

2TT

J

A3/2e

e2 + e2?;2

-A3/2e

2n

1 + ^2

J

(170)

-A3/2e

At the limit of e -4 0 we can write

1=

1 °° 1 lim h = — f du~. e-+o+ 27r_i 0 1 + u2

(171) v '

By using the table integral

we obtain

7=i;arctan(,)|-00 = i - ^ - ( - f ) ]

= i,

(172)

which is valid for any order of A3. (This results from an implicit assumption that the surface in the vicinity of the observation point is flat.) 3.11.2. Calculation of J-type

integrals

In a similar fashion we can write the following relations: X\ — x\ = —u The following steps are self-explanatory:

127

X3 — x'3 = —e

994 A. R. Baghai-Wadji zi+Ai/2 Jt=

J dx\,

-Tl3

dG{x1,xz\x'1,x'z)

xi-Ai/2 x1 + A 1 /2

=

_J_

dx> 1

f

27T

J

H-Aa/2

(Xl

J.x

A t /2

-At/2

2^ y

-x3

z

- X[ )2 + (13 - 4 ) 2

d

=


v r ^ 2^ y

(173)

-Ax/2

3.12. Semi-infinite domain dyadic Green's tion in piezoelectric media with semi-space shear horizontal waves

functions for wave inhomogeneity:

propaga-

We again focus our attention on the propagation of shear horizontal polarized waves which are specified by the transversal mechanical displacement component 112 and the electrical potential tp. As excitation sources we consider both line charges and line forces. The following problems will be covered: a piezoelectric half-space excited by a line charge and a line force. The sources are embedded in the piezoelectric medium. Our concern will be the determination of the mechanical displacement distribution U2(x, z) in the substrate and the potential distribution
0 0 _C,._2L_,v..2 44557 - pu)

_1 C4_

ei5_/en C4

C44

C44

-ei5Q^s

\

/

\

(

f T23

0 0

«2

/

\D3 J

«2 f

dz

T23

\D3 J

A staightforward calculation shows that the corresponding eigenpairs are:

128

\

(174)

Theory and Applications of Green's Functions (

0

/

\

0

\

1

1 A=

995

(175)

A = - | & | <=>

\k\& e15|fc|

-eisl^l

V -£ii|*l

/

(

\

1

V en|*|

/

/

1

\

ei5/eii

eis/eii

(176)

- A t <=>

Xt<=>

C44A4

—CnXt

0

0

Having the eigenpairs, we can set up the solution ansatz for the field quantities which will enter the interface and boundary conditions /

u2(x,z\k)

I

\

0

\

23

e>kxe-e 1 5 |fc|

e15|fc|

T (x,z\k) )

\

ejkxe\k\z+a(2)(kj

a^\k)

D3(x,z\k)

0 1

1


\

/

V -£u|*|

/

V £n\k\ J

/

\

t

1

W3)(*0

e>«xeMZ

W( +a^>(k)

1 C15A11

\ gjfcig-Ajz

—C^\t

Ca\t

0

0

(177) The unknowns ay\k) 3.13. Semi-infinite

will be determined from the interface conditions.

dyadic

Green's functions

for piezoelectric

half-spaces

We are now prepared to derive Green's functions associated with a semi-space piezoelectric substrate which is capable of supporting shear horizontal waves along the substrate surface. Based on the piezoelectricity assumption, there are two ways of exciting the semi-space: we can excite the substrate either by an electrical line charge or equally

129

996

A. R.

Baghai-Wadji

lice spate

X a piezoelectric substrate with material parameters £

11 ,

e

i 5 , ^44

-*•

a line charge + a line force Fig. 5. A line charge and a line force which coincide at the point {i' = a,z' = c) within the substrate in the lower half plane (z < 0).

well by a mechanical line force. While the location of the line force is limited to the substrate region, the line charge can reside everywhere in the space. In this subsection we focus our attention on sources which are located within the substrate. To cover problems arising in practice, the next subsection will be concerned with the medium excitation by a line charge above the substrate? Results from these two sections will allow the investigation of the properties of the involved Green's functions. However, as the reader will see, it is necessary to consider the excitation of two welded piezoelectric semi-spaces, in order to investigate the underlying reciprocity properties of the Green's functions involved. Two welded piezoelectric semi-spaces will be analyzed in the final part of this section. 3.13.1. Line source excitation: sources are located in the lower half space We consider a line charge a at {xa, za) and a line force r positioned at (xT, zT) within the substrate (in the lower half plane (z < 0)), Figs. (5) and (6). We obtain the following results for the Green's functions. The electric potential response in the upper semi-space (z > 0):

i A piezoelectric substrate enclosed in a metallic package is the basic building block of most microacoustic devices. Under the assumption of ideal electric conductivity the metallic parts in the devices can be regarded as a collection of line charges. In an analogous way mechanical loading of the substrate and the mechanical tensions between the substrate and the package can be modeled by a collection of line forces with a •priori unknown strengths.

130

Theory and Applications

of Green's Functions

997

region I liee\p.u.e

Z ii

region II £

11 ,

e

x

C

i 5 , ^44

a line charge + 1 a line force 1

region III £

11 ,

e

!

•

1

..

1 1 .k '

•

i 5 , ^44

Fig. 6. A plane z = c together with the interface plane z = 0 divides the geometry into three homogeneous regions.

^*tp,a \^i Z\%ai Z01 Za\k)

1 £0 + £11 e

1

^44^

1*1° 4 4 |

fc|

~

G<£\x,z\xT,Zr\k) 1 1 =-ei5 £o + £ n | f c | C

jfc(a;-x ff )

eo+e n

1

1 15 £ l l £0 + £ l l |fc| Q

ejk(x-

-|fc||z-^„

£0 en

1 At

ffcf

e Jfc(a;-x a ) e -(|fc||z|+At|2,

eo_£^ eo+en e n

pjHx-xT)

-(\k\\z\+Xt\zT\)

2«__£n_£Li **|fc|

(178)

eo+en e n

The electric potential response in the lower semi-space (z < 0):

131

(179)

998

A. R.

Baghai-Wadji

G<$(x,z\xa,za\k) ••

= J-^eJ^-'^e-l*!!*-^! 2 e n |*|

•, g p - g n g . . ^ t , -J £2 £15. -*• e o + e n 4 4 | f c | e p + e n e n 7fe(a-z„)

1

2en |*|

44

P2 C 15_

fc| |fe|

ee oo + + ec nn eeitl

1 x

2 e n 2 C 4 4 At

_Yfc(a-x^1c-A,lz-z„ _£fl £lfi. e 0 + £ l l e i l .,-fc(x-x„1_-A,lz+z.,l

1 ^ T ^fc| r + 2

2 e i i C 4 4 At cI

e

£

15

44

^ _ _^a_£n |fc|

eo+en en

1

°

I

E l l 2 £0 + e n | * | CAA& 44

1*1

+_e|^—eo— 1

+ |fc|z t7 |)

|fc|

M*-x„)e-m\z\+xtu„\)

(18Q)

EO+EII e n

= _ _ £ " _ le*<*-^>e-A'l*-^

G^(x,z\xT,zT\k)

2 e i i G 4 4 At

1 / ^ .Ai_ 4-

eis_

ejfc(x-xa)e-(A,|z|

^— &• eo+eu e n

1 44

eo

1 ^44 |fc| 1- e o + £ l l

2 £ n C 4 4 At £ +

-|fc||z+z„l

c 4 4 n?r - - S o - S u5..

A, 44

e „2

i5

e u c J f c ( 3 ; _ X T ) c _ A t |z+z T |

£0_£LL

|fc|

eo+en en

£i£_i2_J e n eo + £11 1*1 £ , , £ . 4 4

W

I

e J*(*-*i-) e -(|fc||z|+A t |z,-|)

Q

8 1

S

S2—& £o+£ll eil

The elastic displacement response in the lower semi-space (z < 0): G^%(x,z\xa,za\k)

= __!^_lei*(*-x.)e-At|z^| 2 e n C 4 4 At .

2

eis^ 1 W4]fc[ -r 2 £ n C 4 4 At £ A. 44

I

e

l

5

£n

£ o

|fc[

£ Q + e i i £ l l c7 - fc(a! - a;
£a_£L eo+en e n

1

L _ _ _ _ e J ^ - ^ ) e - ( A t | z | + |fc||z„|)

eo + C11 1*1 CAA& 44

G^r(x,z\xT,zT\k)

|fc|

^ —

,182)

^

e o + e i i £11

= - - L - U i*(*-xT)c-*.l*-^ Z U 4 4 At

6

J. 1 44ffi + e 0 +£ii^ e . 7 fc(x-x T ) e -A t |z+z T | 2C 4 4 At cA. 2± - g " £ k °44|fc|

eo+eil£ll

132

(183)

Theory and Applications

of Green's Functions

999

a line tliarye

1 ree sp.it. e

X

a piezo-electric substrate with material parameters £

11 ,

e

! 5 , C-44

Fig. 7. A piezoelectric half-space when the exciting line charge with the cartesian co-ordinates a and c is located above the substrate surface.

3.13.2. Line charges reside outside the substrate In this section our concern is the derivation of Green's functions associated with a piezo-electric half-space when the exciting line charge with the cartesian co-ordinates (xa,za) is located above the substrate surface, Figs. (7) and (8). The electric potential response in the upper semi-space (z > 0):

G^\x,z\xa,za\k)

,„ >(T , . , - , „ „ , - „ , . . , . 1

+•

1

1 1 = J_J_ei*<*-*->e-l*H*- 2 -l 2eo(Jfep

.. e n - e n /-» A, 1 eo+eii 44l*= I

_£fl

£li

eo+cii eiLgj'*:(3:-3:^) e -|fc||^+z
(184)

T/ie electric potential response in the lower semi-space (z < 0):

1

G^(x,z\xa,za\k)

C

1

*4]k\

'°44|fc| 1 £lie0

+ £ii\k\

1 eMx-xa)e-(Xt\z\ Q

At

ejfc(x-xa)e-|*:||2-z„|

eo+eiien

+ W\z,\) £fl_£ii

77&e elastic displacement response in the lower semi-space (z < 0):

133

(185)

1000

A. R.

Baghai-Wadji

region 1 a line charge

tree space

1 region 11

c

'k

tiee spate

J

X

!

region III £

1 1 , e i 5 , *~-44

Fig. 8. Subdivision of the above geometry.

1

G^x,z\xa,za\k) =

ei5

1

ejk(x-xa)e-(\t\z\

_ — — _ - _ £O + £II\K\

-j

CAAH

3.13.3. Dyadic Green's functions for two semi-infinite electric substrates supporting stonely waves

+ \k\\za\)

(186)

£fi_£ia

piezo-

Consider two semi-infinite piezo-electric substrates which occupy the regions z > 0 and z < 0, Figs. (9) and (10). Let the semi-space z > 0, the upper region, be characterized by parameters C 4 4 , e" 5 and e"j, and the semi-space z < 0, the lower ^ . . region, be characterized by the parameters C 4 4 , e 1 5 and e n . Consider first a line charge and a line force within the upper half-plane, and then a combination of a line charge and a line force which are both located in the lower half-plane. (The reader may find interesting details regarding the derivation of the associated dyadic Green's functions in Ref. 9.) Here, we merely give two representative examples for the Green's functions.

134

Theory and Applications

of Green's Functions

a line charge + a line force

a piezo-electric substrate with material parameters o ( u ) p (u) C l l , e 1 5 , <-44

X a piez.o-electric substrate with material parameters

eO)

C

ll ,

~«

C

r(1)

15, ^44

Fig. 9. Two piezoelectric semi-spaces.

region I o

C

(u)

ll ,

a line charge + a line force

p (u) e

1 5 , <-44

1f

region II o p (u) r(u) C l l , e l 5 , C44 (u)

(

Z

1

X region III n0) C

ll ,

e

1 5 , L.44

Fig. 10. Subdivision of the above geometry.

135

1001

1002

A. R.

Baghai-Wadji

G^Hx,z\X
i

+

= _l_±e**(*-*.>e-l*ll*-*.l

£

I gn+en C44T^ + G44]^ -

e

ii£ii(£ii+£n)

'i J "

ii

f

iieiiveii+eii)

xe J'fc(a:-a:a) e -|fc||z+z^|

( e 15)

1

(e?s) 2

1 1^4|fc|-g44|fc|+£j] £g(£j;£y)

ik(x-x„)

-A?|z-zJ

o 4 4 | f c | +o 4 4 | f c |

, e « i e {;' (e v; e r i)

xeJk(x-xa)e-\f\z+za\ e

gnei5-£iieis

i5

£

( ?i)

2

£

£

n+ ii

x

pjk(x~xa)p-(\k\\z\

1*1 7 ^ , 7 ^

+ XY\z^\)

(efreJB-e^efr)' 11

£ ll£ll(£ll+£ll) jfe(»-^) -(AJ'|zH-|fe||z e -fc(«-*e ) -(Ayizi | ||z.i e?5 £ y i e ' 1 5 - £ ' e y 5 i eJ g e + fc < 7 |)) \M \l £ lru ( £ ?i) 2 £+4i 1*17^„ A? ^ ; A] - « ^J. rJl p-u >27J« *£. _i_ n ±L _ t £ U e 1 5 ~ £ U e 1 5 ) i(£ii+£ii)

l

;

G & J W l * * >**!*) = 1 £

£

£

i1eyr,-£ne'R 1

^

£

'n

£

n+ n

n 1*1 7T* A,

|*| ^ & +c" £ _ (£'i^s-£ne'5)2 W4| f c | + ^ 4 |fc| ^ ^ ^

T 7 « A,

C 4 4 | 4 + G 4 4 -i^ -

3.14. Infinite-domain tal polarized wave

e**(*-*,) e -(A?W+|k||z,|)

(188)

(£iiei5-£ne1B)2 £ ." £ '" £ j ' l £ '" ii ii( ii+ n)

dyadic Green's functions propagation

for the analysis

of

sagit-

Considering a line force embedded in an isotropic elastic half-space, the derivation of Green's functions for sagittal polarized wave propagation has already been discussed in Ref. 24. We denote the distance of the line force in the interior of the domain from the surface of the semi-space d. By letting d go to infinity, we can then obtain the infinite-domain Green's functions from the half-space Green's functions. This section is devoted to a direct derivation of the aforementioned infinitedomain dyadic Green's function. The derivation is based on eigenvalues and associated eigenvectors of the governing and constitutive equations.

136

Theory and Applications of Green's Functions

1003

Statement of the Problem: We assume the entire space to be filled with an elastic medium characterized by the elastic constants C\\ and C44 and the mass density p. Furthermore, we assume that a line force located at the point (x',z'), and oriented in x-direction (TIS(X — x')S(z — z')e"x), oscillates in time according to exp(ju;i), and excites the medium. The excitation of the medium is uniquely determined by the resulting elastic displacements, i.e., Ui(x,z) and u3(x,z) functions. In order t o signify the localized, delta-function-like nature of the source, we use G\{x,z) and G3(x,z) instead of U\(x,z) and u3(x, z). In addition, in order to indicate the direction of the force, which in the present case is the rc-axis, we write Gu(x, z) and Gzi{x,z). Finally, by writing Gn(x,z\x',z') and G3i(x,z\x',z'), we also provide the co-ordinate values of the above-mentioned line force. Analogously we speak of a line force T3<5(a; — x')S(z — z')e"z and of the associated elastic displacement fields which we denote by G-j,3(x,z\x',z') and Gs3(x, z\x', z'). Defining the longitudinal and transversal bulk velocities Q and ct to be c 2 = C\\/p and c 2 = Cu/p, and the quantities X^t = (k2 — ui2/c2 J 1 / 2 we obtain the following eigenpairs:

/

5k K*>

jk

\

2c 2 A;

V -^tJk

<*

-2c 2 A;

V -2
- ft /

.ih.

At

A+o

\

*>

-2k2^ + if

2k2£ - if \

-2c2tjk

)

\

-2c2jk

J

The eigenvector in our diagonalized form is (Ui(k), U3(k), T13(k), T33(k)Y. Using these eigenpairs and satisfying the interface conditions on z = z' we obtain the Green's functions in (189).

G11 (3:3 -x'3\k)

= -

-ai\xx-x'<,\ 2u; 2 a,

, +

a t -at|x3-x^| 2UJ2

Gl3(x3

jk - x'3\k) = - ^ s i g n ^ s - z'sXe-"'!* 3 "^! _ e - « t | * 3 - 4 l )

G33(x3

- x'3\k) = ^ e ~

a

^ - ^

k2 2w2at

a-at\x3-x'3\

(189a) (189b) (189c)

Notice that in these expressions the multiplicative exponential term e^Xl~x^ has been suppressed for the sake of simplicity. The decaying constants in 2-direction, i.e., the eigenvalues aitt are defined as a^t = (k2 — w 2 / ^ ) 1 / 2 , where ci and ct, respectively, denote the longitudinal and transversal bulk wave velocities.

137

1004

A. R.

Baghai-Wadji

3.15. Asymptotic limits of the Green's functions wavenumber domain k ^> 1 3.16. Self-action

analysis

in vector

field

in the far field in

the

problems

In preceding subsections, which dealt with horizontal scalar waves, we found that the self-interaction calculation can be performed either in the spatial domain or in the wavenumber domain. Furthermore, we have demonstrated that the calculation in the wavenumber domain is significantly simpler. This is an encouraging result and gives rise to the next question: is it possible to extend our ideas to include vector fields? The main objective in this subsection is to show that our solution concept, proposed in the foregoing section for scalar waves, is also valid for vector fields. However, it turns out that, in contrast to scalar waves, more t h a n one term must be retained in the asymptotic series in order to adequately reflect the fine scale structure of the problem. In many engineering problems we will be concerned with the interaction analysis of sagittal polarized waves with surface disturbances, formed as ridges or grooves, on the surface of a piezoelectric semi-space. The analysis employs the BEM and involves infinite domain Green's functions associated with the problem. It should be emphasized that the underlying Green's functions have to be known in real space. Generally, while the analysis of mutual interaction is fairly simple and straightforward, the self-interaction calculation is rather cumbersome. The major steps in calculating the self-interaction using real-space Green's functions are given below. Standard Procedure:

• Transform the underlying system of inhomogeneous partial differential equations from the spatial domain into the wavenumber domain.

• Calculate the Green's functions in the wavenumber domain by inverting the inhomogeneous algebraic system of equations (derived in the first step).

• Transform the Green's functions into real space.

• Calculate the derivatives of the Green's functions with respect to the spatial variables. • Calculate the asymptotic limits of the derivatives of the Green's functions in the near field in real space.

• Integrate the asymptotic limits to obtain the self-interactions.

Assuming an isotropic elastic medium (characterized by the velocities c; and ct), and denoting the asymptotic limits of the infinite domain Green's functions Gij(x\x') in the near field (R\\ < 1) by 5 y ( x | x / ) , we obtain the following result:

138

Theory and Applications

dx[ dx\ 3 an - a^ , 2 ( j ! - a^) 3 ~

„2

T->2

"•" .2

. aGn(x|x')

^ f t i W

.9a;; 1 x3 — x'z

dx\ 2 (0:3 — x'3)3

fl2

c2

1 13 - X3

Ri

c2

c;

#j

. dG 33 (x|x')

47T

da^

C?

~ 47T

i?2

^ dx'3 3 x 3 - x'3

r2

R2

itf

C2

a5 3 3 (x|x0 Sajj

C2

l T 0533(xl^)

~

ylyU>

2 (a?3 — x'3)

-+c 272

JJ2

D#4

(,j.yi;

(192)

=

+

*

^2

+

p4

^4

c ?

^

=

dx'3 2 (13 - a/3)3 , I 1 3 - 4 „2

(193)

2 (a?i - a;;)3

Sii-ii c?

l r r a5 3 3 (xlxQ

l i i - a^ 2 (a^ — a^) r>*' ^+ 32 R2 R4

=

2 (si - a^) 3

_ l i i - i j C2

p4

/

) ^ l 7 r a5 1 3 (x|x') 9a:3 da:3 1 zi — a;i 2 (a;i — x^)3 ,2

.2

3 i 3 - 4 , 2 (a 3 - x'3)3 c2 i? 2 ^h-j j 53* c2

4 , ^ 3 ^ „

l j r 0G 1 3 (x|x

n>2

=

2{x3-x'3)3 c? flJ

itf

c

r2

1005

dSn^x')

_lx3-x(i

.2

2 ( g l - a;;)3

h i - » ; +

p4

^ ^ 47T

47T

of Green's Functions

"+" „2

R2

2 (x 3 - x'3)3 „2

p4

Uy{V

Preparatory Calculations: Based on the Taylor power expansions \/l - 1

a:2

2 p

1

a;

VI-a;2

139

x< 1

(196a)

a; < 1

(196b)

2

1006

A. R.

Baghai-Wadji

and ex « 1 + x

x< 1

(197)

which are valid for vanishingly small values of the argument x, the following manipulations are self-explanatory:

„,

lw2 1

, (198a)

^ " ^ ' - ^ j * ! i _ i u3 ai,t * |fc| +' 2o — c\tT \k\ e-a,lt|*3-^3l

(198b) lw2 1

„ e -|A=ll-3-.T 3 | ( 1 + ±!%--L\x3 2c ; , t I'M

- X'3\).

(198c)

Substituting these asymptotic expressions for aij, l/<*z,t and exp(—&ij\x 3 — x3\) in the expressions for the Green's functions in Eqs.(189), we obtain their asymptotic limits for k » 1. We start with G\\. Substituting (198), performing the multiplications, neglecting higher-order terms, and rearranging, we obatin

+ 4 ) 1 * 3 - 33|e-lfcN*»-*sl

S i i ( z 3 - x'3\k) = \(-~

-k$+&w\e~Wi"~*-

(199)

Similarly, we obtain S13(x3 - x'a\k) = - h \ - \)(x3 v

4 cf

ct

- x'3)jSign(k)e-^x^x'^,

(200)

and

S33(x3

- x'3\k) = T ( — 2 + -5)\x3 *

c

t

- 4|e-l fc H*3-*3l

H

- 7 ( 4 + 4)^T eHfc||X3 '" 41 4 c?

( 201 )

k

4 \ \

So far we have determined the asymptotics of the Green's functions in the far field in the wavenumber domain (k >• 1). Our next concern is the transformation of the above results into real space. As is obvious from the above results, t h e functional structure of the asymptotics of the Green's functions is much simpler than that of the Green's functions themselves. This property significantly simplifies the transformation into real-space. The following integrals will play an important role in further discussion: 31

140

Theory and Applications

of Green's Functions

1007

oo

/

dke-pkcosqk

=

0

P

dke-pksinqk

=

0

„

(202a)

„

(202b)

o

I oc

/

dk

e

9

pk

cosqk 1 j - ^ - = --HP2 f

2

2\ + qf)

(202c)

(For the conditions under which the third equality is valid please refer to the exhaustive discussion in the previous section.) Based on these integrals, the transformation of S\\(xz — x'3\k), 513(2:3 — x'3\k) and 533(2:3 — x'3\k) into real space is an elementary task. Note that in the process of this transformation the oscillatory exponential term x x ejk( -L- i) m u s t be accounted for. We omit the details, and summarize our results:

J _ JL_ _ 1 (x1 -x'Jjxa X)

^3(x|x') = ^ ( 3 - 4 ) V 1 1

«

=^-3

3.17. Real-space near-field Green's functions

1

+

l.(x3-x'3)2

T~"

- x's) 1 1

^-"nf^ + T^

asymptotics

(203b) +

of the spatial

1 1

^2lnRi derivatives

(203c)

of

In order to find the spatial-domain near-field asymptotics of the spatial derivatives of Green's functions an important property can be utilized: the asymptotic limit-process and the process of derivation are commutative in real space. Thus, simply by calculating the Xi and £3 derivatives of the asymptotic expressions S'ii(x|x / ), 5i3(x|x') and 533(x|x / ), we find the required asymptotics. For the details the reader is referred to Ref. 9. 3.18. Calculation of i?<^Cl—asymptotic limits of the Green's functions based on k^$>l—asymptotic limits of the underlying eigenvalues and eigenvectors The primary objective of this section is t o show t h a t the near-field behavior (R -C 1—asymptotic limits) of the Green's functions in real-space can be obtained from the far-field behavior (k ~^> 1—asymptotic limits) of the underlying eigenquantities in wavenumber domain in the following way: • find the k 3> 1—asymptotic limits of the eigenvalues and eigenvectors. • Construct the relevant field variables by superposing the limits obtained from the first step. This results in the k 2> 1—limits of the field variables. (A certain

141

1008

A. R.

Baghai-Wadji

number of unknown coefficients enter into our calculations, which have to be determined from the boundary conditions.) • Using the k S> 1—limits of the field variables fulfills the problem's boundary conditions by assuming a delta function excitation. This leads to the values of the unknown coefficients from which the k 3> 1—limits of field variables can be calculated. As will be seen in this section, the resulting field variables are the k » 1—asymptotic limits of the Green's functions which we are seeking. This fact will prove the following commutativity property: the process of satisfying the boundary conditions, and the k 3> 1—process are commutable. • Once we have found the k » 1—asymptotic limits of the Green's functions, simply by inspection a Fourier-transformation yields the R -C 1—asymptotic limits of the Green's functions (in the near field in real space). Remember that they are exactly these limits which play an essential role in the self-interaction analysis in BEM-applications*

3.19. Line force source excitation of an unbounded, medium for sagittal polarzied wave excitation: calculation of i?
elastically-isotropic functions

We assume that a mechanical force (per unit mass density) excites an infinitedomain isotropic elastic medium. Furthermore, we assume that the line force oscillates in time according to exp(ju>t) and that it acts at the point (x',zf) in a :r2-co-ordinate system. There is variation in y-direction (d/dy = 0). We denote the components of this force vector in x- and ^-direction by TJ and T%, respectively. The problem is to find the resulting elastic-displacement functions Ui(x, z) and 1/3(2:, z) (which are already our Green's functions, due to the particular J-function excitation) in the ultimate vicinity of the line force. Thus, our goal is the presentation of an alternative way for the determination of the R -C 1—asymptotic limits of the Green's functions. 3.20. Solution

strategy

The analysis follows the exact same line as for the construction of the infinitedomain Green's functions in the previous sections. The only difference is that here we fulfill the boundary conditions with k 3> 1—asymptotic limits of the field variables, instead of with the field variables themselves. For this purpose we proceed as follows: • Subdivide the (a;, z)-infinite domain into two semi-spaces z > z' and z < z' by the plane z = z'. (Note that z' is the z-coordinate of the line force considered.) fc

It is possible to convert a linear system of governing partial differential equations, together with the constitutive equations, into an eigenvalue equation for a reduced number of field variables. 9 The solution of the resulting eigenvalue equation leads to a certain number of eigenvalues and the associated eigenvectors. In terms of equivalent relationships we can say that: 1. partial differential equations (PDEs), together with the constitutive equations, can be equivalently transformed into an eigenvalue equation. 2. The information contained in an eigenvalue equation is equivalent to the information carried by its eigenvalues and eigenvectors.

Therefore we infer that the information contained in a given system of PDE and constitutive equations is uniquely determined by the system-characterizing eigenquantities. The boundary conditions merely dictate which of the eigenquantities and how strong in competetion with each other they are present in our formulae.

142

Theory and Applications of Green's Functions

1009

In the following, we call the half-space z > z' region I, while the semi-space z < z' will be refered to as region II. • Find the k » 1—asymptotic limits of the eigenvalues and the associated eigenvectors. • Use the k ~S> 1—asymptotic limits of the eigenquantities t o construct the field variables in regions I and / / . (A certain number of unknown coefficients enter into our calculations.) • Impose the boundary conditions so as to obtain the unknown coefficients involved. This leads t o the k 3> 1—asymptotic limits of the Green's functions involved. • Use inverse Fourier transformation to obtain the R
3.21. k 3> 1—Asymptotic

limits

2

2

2

of the eigenvalues

and

eigenvectors

1,/2

Having A;,t = (k — w / c t ) , using asymptotic expansions which are valid for k 3> 1, and restricting ourselves t o two leading terms, we can find the k ~S> 1—limits of the above-mentioned eigenvectors.

/

{

\

Sf-i^M

\

-Sf + i ^ M

A+*>

\

«*

-2c2\k\ +

fc?!*!-^

V

^ -2<&*-£ J

\+4>

«•

i^M

I

jk

\ J1

I

I

27[jk\k\

-2c t |fc| +

-2c2jk

J

1 |fc| _

\

2c? 1*1

^

-2<&* - £

/

Sf + ^ M

^

2^[JT\W

-2c2jk 3.22. k 3> 1—Asymptotic

limits

of the

field

variables

The reader should be reminded t h a t the components of the eigenvectors stand for Ui(k), U3(k), Tiz(k)/p and T33(k)/p. We denote the k > 1-asymptotic limits of these field variables by Sx(k), S3 (A), t\z(k)/p and tzz{k)/p, respectively. Then, in region I (z > z'), we can write the following relationships:

143

1010 A. R. Baghai-Wadji S{(x,z\k)

= A(k)ejkxex>

z

+ B(k)ejkxe^

z

(204a)

2

+B

kx jk ~ 2cf jfc|fcj ^-fk-\^Tk^ ^

t

1

^^=A(k)(-2cm + B(k)(-

+

-i

^ V

_

p^)e^A. z 1*1 <

lu4l 1 2c \k\ + _ ^ _ _ ) e ^ A - * 2

(204c)

2 — " \„ik \elkxXeeXl jk J

2 * 3 3 ( M * ) _ A(k)( „ W -2co-2.jk- t \

+ B(k) ( - 2c? j * ) ePkxex*z

(204d)

Terms associated with A; and \f are omitted here, in order t o satisfy the Sommerfeld's radiation condition at infinity {z —• +oo). Analogously, by using terms associated with Xf and A+, we obtain the limits in region II (z < z'). 3.23. Interface fields

conditions

applied

to the k 3> 1— asymptotic

limits

of the

The involved coefficients can be determined from the interface conditions on the plane z = z'. Thereby we use the (k 3> 1) asymptotics for the displacement and stress components, rather than these components themselves. A straightforward calculation gives the following result:

S{(x-x',z-z'\k) -_]tLTlP3Hx-x') _

= -X,(z-z') _ I_L_L TlP J*(z-a:')p-A,(2-z')

2u?1 _J^T3e3Hx-x')e-\l(z-z') 2UJ2 _ll.-LTieJHx-x')e-*t(z-z')

Ac2\k\l

4C2|*| JtLTie}k(x-x')e-Xt{z-z')

+

2ui2

+

, J^_n(Jk(x-x')

2^2T3e

-\t(z-z')

/ 2 05)

(M0

>

The appearance of (x — x') and (z — z') in the second equation in (205) suggested the introduction of the form S[{x — x',z — z'\k), instead of S{(x, z\k). As the inequality z — z' > 0 holds true in region / , we can write z — z' = \z — z'\. Using this relation, substituting the k ^> 1—asymptotics of exp(—\i\z — z'\) and exp(—Xt\z — z'\), and reordering, and arranging the terms associated with T\ and T3 into two separate groups, we obtain:

144

Theory and Applications of Green's Functions

1011

S[(x-x',z-z'\k)

= [-!<£- ^>i 'I -\^^)UeM'"%^"'^ + f- l(\ L

4 cl

- \)jsign(k)\z-Z'\]e^x-x\-^z-2\3 ct

(206)

J

Identification of the terms multiplied by T\ and T3 : The term multiplied by Ti represents the k » 1—asymptotic limit of the Green's function Gn(x — x',z — z'\k) in region I (z — z' > 0). Likewise, the term multiplied by T3 is the k 3> 1—asymptotic limit of the Green's function Gi3(x — x',z — z'\k) in the aforementioned region. Denoting these limits by 5f 1 (x — x',z — z'\k) and S{3(x — x',z — z'\k), we can write:

Sl^x

- x \ z - z'\k) = [ - i ( 4 - 4 ) | z - A L

* cl

c

t

- l ( \ + 1) ±_\eM*-x')e-\k\\z-z'\ 4 xcf cf \k\l Si3(x -x',z-

z'\k) = - \ { \ 4

- \)jsign(k)\z

Cl

-

( 207a)

z'\eM—')e-\k\\z-z'\

Ct

(207b)

In order to investigate the behavior of the limits Gu(x — x', z — z'\k) and G\3(x — x',z — z'\k) in region II (z — z' < 0), we consider the term S[! (x,z\k). A similar analysis leads to the results

SU(x-X',z-z'\k)=\--(-s--3)\z-z'\

- i ^ + ^lSi]^'^"1""""'1 SU(x -x',z-

z'\k) = \ ( \ 4

C;

- \)jsign{k)\z

-

(2 8a)

°

z>\eJKx-x')e-\k\\z-z'\_

Ct

(208b)

The expressions in (207) and (208) can be unified by using the fact that \z z'\ = z - z' in region I and that \z - z'\ = -(z - z') in region II. The k > 1-asymptotic limits of the remaining Green's functions, i.e., G3i and G33, can be found analogously. Summarizing our results we can write:

145

1012

A. R.

Baghai-Wadji

Sll(x-x',z-z'\k)=\-\(±-±)\z-z'\

~l(\

S13(x-x',z-z'\k)

=~\(^

+ \)^l}eMx~X

~ ^)jsign{k)(z

Vl*"*-*'!

-

z')ejk<-x-^e-^z-z'^

=S3i(x-x',z-z'\k)

SS3(x-x',z-z?\k)=

\j{-s

L

*

(210)

- ~s)\z -

c

i

(209)

c

A

t

- 1 ( 4 + L) J_]e^(*-*')e-l*llW|

(2U)

Eqs.(209-211) constitute the matrix £_, which is the k » 1—asymptotic limit of the dyadic Green's function Q_. The elements of £ can be transformed into the real domain simply by inspection, to obtain the real-space near-field asymptotics of the Green's functions involved. This transformation, however, has already been performed in a previous section and will not be repeated here. There the elements of <S were derived directly from the Green's functions and not, as was the case here, from the k 2> 1—asymptotic limits of the eigenquantities. This completes our proof of demonstrating that the process of satisfying the boundary conditions and the k 3> 1—process are commutable. 4. S u m m a r y In this chapter we have shown that the governing equations in anisotropic, and transversally inhomogeneous piezoelectric materials can be diagonalized. Details regarding a newly developed symbolic notation, and a recipe for the construction of diagonalized forms have been discussed in Section 2, following a brief introduction in Section 1. Although the presentation of the diagonalized form in Section 2 is selfcontained, it remains restricted to the piezoelectric media. Further complementary discussions on the diagonalization of Maxwell's equations in anisotropic media can be found in Ref. 9. The reader is also referred to the Refs. 32 and 33 which are devoted to the diagonalization of Maxwell's equations in bi-anisotropic inhomogeneous media and Laplace's equation in the anisotropic dielectric and magnetic media, respectively. The latter forms have been developed to analysis waves and fields in large amplitude corrugated periodic structures. Furthermore, the reader may find additional applications of the diagonalized forms in Ref. 34. There, among others, the propagation of electromagnetic waves in photonic crystals with defects has been addressed. Diagonalized forms in Fourier domain represent standard or generalized algebraic eigenvalue equations, which lead to the eigenvalues and eigenvectors corresponding to the underlying differential operator. An efficient algorithm for the calculation of higher-order derivatives of eigenvalues and eigenvectors is discussed in Ref. 35.

146

Theory and Applications of Green's Functions

1013

Section 3 has been devoted to a brief discussion on Green's functions. Two methods for the construction of Green's functions in infinite and semi-infinite media have been presented. The first method, based on the inversion of the underlying differential operator, is suitable for infinite-domain Green's functions. The second method, utilizing the diagonalized forms from section 2, can be chosen to construct both the infinite doamin and the semi-infinite domain Green's functions. Several boundary value problems have been considered, as useful examples, to demonstrate the details pertaining the construction of Green's functions. Much attention has been devoted to the Green's functions associated with Laplace's operator because of their far-reaching significance. The charge neutrality condition, as a regularizing balance law, has been emphasized. These considerations are followed by two recipes for the construction of periodic Green's functions. Many useful applications of periodic Green's functions can be found in Ref. 28. Section 3 closes with a discussion on the self-action calculation which arises in the boundary element method applications. Although here the discussion on self-action analysis seems exhaustive, it only scratches the surface of this pre-eminent research topic. The material presented is an adaptation of my ideas compiled and discussed in Ref. 9. Space limitation has prevented the inclusion of any of my results have been obtained since 1995. Selected topics concerning the self-action calculations, regularization of singular surface integrals, near-field calculations around the edges, wedges, and corners can be found in my articles in the IEEE Ultrasonics Conference Proceedings published in the years 1995-2000. As a possible future research direction I would like to emphasize the construction of Green's functions-based wavelets. 10 Acknowledgments It is my privilege to thank Professor Martti Salomaa, Director of Materials Physics Laboratory at Helsinki University of Technology, for inviting me and initiating a Visiting Professorship (Oct. 1999 through Dec. 2000), which has been sponsored jointly by TEKES, a National Technology Agency, and, the Nokia Research Foundation. It is also my pleasure to extend my thanks to all the department members for excellent support and for making my stay in this distinguished pedagogical and research environment an invaluable and enriching experience. Furthermore, it is my pleasure to thank the editors Prof. Tor A. Fjeldly and Dr. Clemens C.W. Ruppel for their kind invitation to author this chapter. References

1. R.F. Harrington, Field Computation by Moment Methods, Macmillan, New York, 1968. 2. C.A. Brebbia, J.C.F. Telles, and L.C. Wrobel, Boundary Element Techniques, Springer Verlag, 1984. 3. E. Stein and W.L. Wendland (Editors), Finite Element and Boundary Element Techniques From Mathematical and Engineering Point of View, Springer Verlag, 1988. 4. N.I. Muskhelishvili, Singular Integral Equations, P. Noordhoff N.V. - Groningen Holland, 1953. 5. S.G. Mikhlin, Multidimensional Singular Integrals and Integral Equations, Pergamon Press, 1965. 6. R.E. Collin, Foundations for Microwave Engineering, McGraw-Hill International Editions, 1966, Electrical & Electronic Engineering Series. 7. G.F. Roach, Green's Functions, 2nd ed., Cambridge University Press, 1967.

147

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Baghai-Wadji

8. I. Stackgold, Green's Functions and Boundary Value Problems, A Wiley-Interscience Series of Texts, Monographs & Tracts, J o h n Wiley & Sons, 1979. 9. A. R. Baghai-Wadji, A Unified Approach for Construction of Green's Functions. Habilitation manuscript (lecture notes), Vienna University of Technology, Vienna, 1994. 10. A. R. Baghai-Wadji, G. Walter, "Green's Function-Based Wavelets." Accepted for presentation a t t h e IEEE International Ultrasonics Symposium, San Juan, P u e r t o Rico, Oct., 2000. 11. A. R. Baghai-Wadji, Bulk Waves, Massloading, Cross-Talk, and Other Second-Order Effects in SAW-Devices (a short-course manuscript). IEEE International Ultrasonics Symposium, San Antonio, Texas, Nov., 1996. 12. A.H. Fahmy, and E.L. Adler, " P r o p a g a t i o n of Acoustic Surface Waves in Multilayers: A Matrix Description." Appl. Phys. Lett., vol. 22, pp. 495-497, 1973. 13. E.L. Adler, "Analysis of Anisotropic Multilayer Bulk-Acoustic-Wave Transducers." Electron. Lett, vol. 25, pp. 57-58, J a n . 1989. 14. E.L. Adler, " M a t r i x Methods Applied t o Acoustic Waves in Multilayers." IEEE Trans. Ultrson. Ferroelec. Freq. Contr., vol. UFFC-37, no. 6, pp. 485-490, 1990. 15. E. Langer, PhD Dissertation. Vienna University of Technology, Vienna, 1986. 16. R.F. Milsom, N.H.C. Reilly, and M. Redwood, "Analysis of Generation and Detection of Surface and Bulk Acoustic Waves by Interdigital Transducers." IEEE Trans. Sonics Ultrson., vol. SU-24, p p . 147-166, 1990. 17. A.M. Hussein, and V.M. Ristic, " T h e Evaluation of the I n p u t Admittance of SAW Interdigital Transducers." J . Appl. Phys., vol. 50, no. 7, p p . 4794-4801, July 1979. 18. K. Hashimoto, a n d M. Yamaguchi, "Precise Simulation of Surface Transverse Wave Devices by Discrete Green Function Theory." Proc. IEEE Ultrason. Symp., pp. 253258, 1994. 19. P. Ventura, J.M. Hode, and B. Lopes, "Rigorous Analysis of Finite SAW Devices with Arbitrary Electrode Geometries." Proc. IEEE Ultrason. Symp., pp. 257-262, 1995. 20. P. Ventura, J.M. Hode, and M. Solal, " A New Efficient Combined F E M and Periodic Green's Function Formalism for t h e Analysis of Periodic SAW Structures Characterization." Proc. IEEE Ultrason. Symp., p p . 263-268, 1995. 21. R.C. Peach, " A General Green Function Analysis for SAW Devices." Proc. IEEE Ultrason. Symp., pp. 221-225, 1995. 22. V.P. Plessky, and T. Thorvaldsson, "Periodic Green's Function Analysis of SAW a n d Leaky SAW Propagation in a Periodic System of Electrodes on a Piezoelectric Crystal.", IEEE Trans. Ultrson. Ferroelec. Freq. Contr., vol. UFFC-42, p p . 280-293, 1995. 23. B.A. Auld, Acoustic Fields and Waves in Solids, vol. I and II, John Wiley & Sons, 1973. 24. N.E. Glass, R. Loudon, and A. A. Maradudin, " P r o p a g a t i o n of Rayleigh Surface Waves across a Large-Amplitude Grating.", Physical Review B, vol.24, no.12, 1981. 25. A.R. Baghai-Wadji, and A.A. Maradudin, "Shear Horizontal Surface Acoustic Waves on Large Amplitude Gratings", Appl. Phys. Lett, 59 (15), 7 October 1991. 26. R.P. Kanval, Generalized Functions, Series on Mathematics in Science and Engineering, vol. 171, Academic press, 1983. 27. M. Abramowitz and LA. Stegun (editors), Handbook of Mathematical Functions, Dover Publications, Inc., New York. 28. A.R. Baghai-Wadji, H. Reichinger, H. Zidek, a n d Ch. Mecklenbrauker, "Green's Function Applications in SAW Devices." Proc. IEEE Ultrason. Symp., p p . 11-20, 1991. 29. J.L. Bleustein, Appl. Phys. Lett., 13, 412, 1968. 30. Yu.V. Gulyaev, Pisma v Z h T F , 9, 63, 1969. 31. I.S. Gradshteyn and I.M. Ryzhik, Table of Integrals, Series, and Products, Academic Press, 1980.

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1015

32. B. Jakoby, and A.R. Baghai-Wadji, "Analysis of Bianisotropic Layered Structures with Laterally Periodic Inhomogeneities - an Eigenoperator Formulation." IEEE Trans. Antenn. Propag., vol. AP-44, no. 5, pp. 615-621, May 1996. 33. M.T. Manzuri-Shalmani, A.R. Baghai-Wadji, and A.A. Maradudin, "Noise-free Static Field Calculations in Corrugated Periodic Structures." Proc. IEEE-AP, Antenn. Propag. Symp., pp. 1089-1092, 1993. 34. A. R. Baghai-Wadji, Photonic Crystals, lecture notes, Helsinki University of Technology, Helsinki, Fall 2000. 35. S. Ramberger, and A.R. Baghai-Wadji, "Calculation of Higher-order Derivatives of Eigenvalues and Eigenvectors." (In preparation), IEEE Trans. Antenn. Propag.

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International Journal of High Speed Electronics and Systems, Vol. 10, No. 4 (2000) 1017-1068 © World Scientific Publishing Company

NEW PIEZOELECTRIC SUBSTRATES FOR SAW DEVICES JOHN A. KOSINSKI U.S. Army Communications-Electronics Command, AMSEL-RD-IW-S, Fort Monmouth, NJ 07703-5211, USA Recent developments in single crystal piezoelectric materials have focused on the search for "ideal" materials with zero temperature coefficient of frequency orientations featuring jointly high piezoelectric coupling, high intrinsic Q, zero power flow angle, and minimized diffraction effects. In addition, the desired materials should have no low temperature phase transitions, and a physical chemistry conducive to repeatable, low cost growth and wafer scale device production. As difficult as it might seem to find such "ideal" materials, three completely different but strong candidate materials have emerged recently: the quartz homeotype gallium orthophosphate, the quartz isotype calcium gallogermanates (langasite, langanite, langatate, etc.), and diomignite (lithium tetraborate). The current state-of-the-art and prospects for future development of these materials are considered.

1. Introduction To date, single crystal quartz (oc-Si02) and lithium niobate (LiNb03) are the most widely used single crystal piezoelectric substrates for SAW devices. Each of these materials has certain properties that make it attractive for specific applications. In the case of quartz, the most interesting features are the zero temperature coefficient of frequency jointly with zero power flow angle, high Q, and non-zero piezoelectric coupling for the ST-cut; these characteristics lead to widespread use in narrowband filters and precision resonators in the VHF and UHF range. In the case of lithium niobate, the most interesting feature is large piezoelectric coupling leading to widespread use in broadband and low insertion loss filters. However, the lack of a zero temperature coefficient of frequency is a serious limitation for the use of lithium niobate. Recent developments in single crystal piezoelectric materials have focused on the search for and development of "ideal" materials. Traditionally, "ideal" materials were considered to be those featuring jointly high piezoelectric coupling, zero temperature coefficient of frequency orientations, and high intrinsic Q. However, in the context of substrates for SAW devices, additional criteria have been imposed. The zero temperature coefficient of frequency orientations must also feature zero power flow angle jointly with minimized diffraction effects, no low temperature phase transitions, and the physical chemistry of the material must admit repeatable, low cost growth and wafer scale device production. As difficult as it might seem to find such "ideal" materials, three completely different but strong candidate materials have emerged recently: the quartz homeotype gallium orthophosphate, the quartz isotype calcium gallo-germanates (langasite, langanite, langatate, etc.), and diomignite (lithium tetraborate). Gallium orthophosphate and the calcium gallo-germanates both belong to trigonal symmetry class 32, and hence have much in common with ct-quartz. Diomignite belongs to tetragonal symmetry class 4mm as do certain piezoelectric ceramics. The current state-of-the-art and prospects for future development of these materials are considered. 151

1018

J. A.

Kosinski

2. Quartz Homeotypes - Gallium Orthophosphate 2.1. General comments Alpha-quartz is unquestionably the most successful single crystal piezoelectric material, with nearly "ideal" characteristics in many respects. It follows naturally that quartz homeotypes should be investigated for similar or potentially superior characteristics, and in fact it has been found that berlinite (a-AlP0 4 ) demonstrates superior piezoelectric coupling as compared to quartz. Unfortunately, extreme difficulty has been experienced in growing high quality berlinite crystals of commercially viable size. Recently, gallium orthophosphate (oc-GaP04) has been proposed as another quartz homeotype of interest. This new material belongs to the same family of M 3+ X 5+ 0 4 crystals as berlinite, constructed by the alternate replacement of half of the silicon atoms by trivalent gallium and the other half by pentavalent phosphorous atoms.1 Preliminary results indicate similar good characteristics for gallium orthophosphate, with the coupling coefficient of the GaP0 4 AT-cut larger than that of berlinite, and approximately twice that of quartz.2 Further, gallium orthophosphate demonstrates a superior thermal stability, transitioning directly to a p-cristobalite form at 933°C as compared to the o>P phase transition near 580°C for quartz and berlinite.3 2.2. Crystallography As a quartz homeotype, gallium orthophosphate belongs to symmetry class 32, characterized by a single three-fold symmetry axis and three equivalent two-fold symmetry axes as illustrated in Fig. 1.4 The three-fold axis is also a screw axis, leading to right- and left-handed enantiomorphs belonging to space groups P3i21 and P3221 respectively,1 hence both electrical (Duaphine) and optical (Brazil) twins are possible. As noted, the crystal structure is similar to that of a-quartz,5 with half of the silicon atoms replaced by trivalent galjium and the other half replaced by pentavalent phosphorous atoms. Consequently, the unit cell extent along the c-axis is twice that of quartz. Measured values of lattice constants are listed in Table 1. There are three formula weight per unit cell. Analysis of the data near room temperature lead to values of a=4.901+0.003A and c=11.046±0.008A at 25°C corresponding to an x-ray density of 3571±7 kg/m3 which is consistent with the previously reported values as listed in Table 2. Thermal expansion data are presented in Table 3. Published data on the thermal stability of the a-phase of gallium orthophosphate are listed in Table 4. There is substantial variation in the reported phase-transition temperature data. The phase relations in gallium orthophosphate are illustrated in Fig. 2.12 The behavior of gallium orthophosphate is distinctly different than that of quartz and berlinite. The material transitions directly from the a-phase to a P-cristobalite form at 933°C, whereas quartz and berlinite undergo an intermediate a-p phase transition near 580°C.3 In consequence, gallium orthophosphate devices may be processed or operated at significantly higher temperatures than comparable quartz or berlinite devices.

152

New Piezoelectric Substrates for SAW Devices

Ski

Ek

£!!:: •

•

•

AT

\ : : \

• ©

. . . >® x

•

•

V:

• ^5"^®

X,X i

1019

AS

6 2 2 2 0 _! 13

Fig. 1. Class 32 symmetry elements and matrices for equilibrium properties [Nye, 1960].

Table 1. GaP04 Lattice Constants. a (A) 4.874±0.002 4.899+0.001 4.901±0.001 4.897+0.001 4.934±0.002 4.973+0.002 4.90 4.905 4.901±0.003

c(A) 11.033±0.004 11.034±0.002 11.048+0.001 11.021+0.002 11.075+0.005 11.105+0.006 11.05 11.050 11.046+0.008

To(°C) -100 20 20 100 500 750 r.t.

— 25

Reference 6 7 1 7 1 1 8 9 this work

Table 2. GaP0 4 Mass Density. Mass Density (kg/mJ) 356x 357x 3570 361x 358x 3570 3571+7

Method measured x-ray

To(°C) r.t. r.t.

—

—

x-ray x-ray

-100 20 25 25

— x-ray

Reference 8 8 1 7 7 10 this work

Table 3. GaP0 4 Thermal Expansion.

aj 1 / (ppm/°C)

a f f (ppb/°C2)

a^

17.9 5.3 10.52 9.02 10.15

—

4.6 1.2 1.70 3.38 3.34

35.4 35.4 14.58

(ppm/°C)

a g } (ppb/°C2)'

T„(°C)

Reference

....

....

11 12 13 14 15

2.0 2.0 2.52

153

r.t. 25 27

1020

J. A. Kosinski

P-phase P6222

thermal decomposition >1327°C

(1687 °C) P-cristobalite F43m 933 °C 578 °C 533 °C a-phase P3t21

a-cristobalite C222!

Fig. 2. Phase relations in gallium orthophosphate.12

Table 4. GaP04 Critical Temperatures. Transition Point (°C) 1077 1000
Melting Point (°C)

— — — 1670

— — —

Reference 16 11 17 3 18 10 18

2.3. Crystal growth The growth of gallium orthophosphate has been described in detail by several researchers.81019"24 Gallium orthophosphate crystals have been grown hydrothermally in silica, pyrex, and teflon,24 and tantalum-lined19 autoclaves using sulfuric, phosphoric, and hydrochloric acid solutions. The material features a retrograde solubility in all acids; nutrient material is dissolved in the cold region and crystal growth occurs in the hot 19,20,25 Starting materials have been prepared by solid state region of the autoclave. reaction of Ga 2 0 3 and NH 4 H 2 P0 4 with thermal treatment in H 3 P0 4 ,' reaction of gallium hydroxide with phosphoric acid, and reaction of gallium metal first with nitric then phosphoric acid.19 Early results reported the use of berlinite seeds;19'20 large size, defectfree gallium orthophosphate seeds have been reported recently.23 Variations of hydrothermal growth reported for gallium orthophosphate include the slow heating (SHT),19'22 horizontal composite gradient (HTG),8'19 and vertical reverse temperature gradient (VTG) methods.19 SHT and HTG growth typically occur in phosphoric acid over the temperature range of 150°C to 180°C with a temperature gradient of 1°C-6°C. VTG growth typically occurs in sulfuric acid at a temperature near 230°C with a temperature gradient also of 1°C-6°C. The growth habit varies markedly

154

New Piezoelectric Substrates for SAW Devices

1021

with the solvent used. Growth in hydrochloric acid exhibits a favorable Vx/Vz ratio, but an overall slow growth rate on the order of less than 0.05 mm/dxface. Growth in sulfuric acid occurs at higher temperatures and hence results in reduced OH content of the grown crystals, but the Vx/Vz ratio is always undesirably high. Growth in phosphoric acid exhibits a favorable Vx/Vz ratio and an overall good growth rate, however with elevated OH content due to the reduced growth temperature as compared to growth in sulfuric acid. All solvents yield growth rates Vy less than 0.01 mm/dxface. At present, growth in phosphoric acid is recommended as most suitable for commercial production.23 An alternative technique using direct solubility in orthophosphoric acid above 335°C has also been reported.26 The perfection of as-grown gallium orthophosphate crystals has been studied by IR spectroscopy819'22 and X-ray topography.1019'2127 A solution of 5% HF and 10% HC1 has been used as an etchant to reveal twins.19 Both Dauphine and Brazil twins have been observed. An absorption band at 3167 cm"1 has been associated with the OH content of the as-grown crystal; the absorption coefficient is then calculated as

a:

log V"cm J

^800

(1)

T

V 3167

where d is the sample thickness in centimeters and T represents the infrared transmission at the specified wavenumber.19 The correlation between a and material Q has yet to be established for gallium orthophosphate. Phosphoric acid has been used as an etchant to reveal etch pits.22

2.4. Material properties The form of the elasto-piezo-dielectric constants matrices (augmented by the entropytemperature relations) for symmetry class 32 are shown in Figure l.4 The material constants of primary interest for piezoelectric device design are the dielectric, piezoelectric, and elastic constants of the material, along with their temperature coefficients. Reported values for these constants are listed in Tables 5 and 6, 7, and 8 respectively. The dielectric constant data are separated into two tables to emphasize the difference between the values sT at constant traction and the values s s at constant strain. The dielectric constants are typically measured using a capacitance bridge at a frequency of 1 kHz; these values correspond to sT. However, the commonly used constitutive relations require the values of es. These values are calculated from the measured sT in conjunction with the elastic and piezoelectric constants as

s'W-ex^xfeJ E

1

'

(2)

where e and c represent respectively the piezoelectric and isagric elastic constants matrices and [e]T represents the transpose of the piezoelectric constants matrix. The reported values of the elastic and piezoelectric constants have been obtained from a variety of methods, including Brilloin scattering, pulse-echo, and resonator methods.

155

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Kosinski Table 5. GaP0 4 Relative Dielectric Permittivities at Constant Traction.

E E

T

ET

ll 7.8 6.5 5.2±7%

E33

10.3 6.7 5.1 ±7%

Frequency

T„(°C)

Reference

10 kHz 1 kHz 1 kHz

r.t.

24 16 28

— r.t.

Table 6. GaP0 4 Relative Dielectric Permittivities at Constant Strain. Es

•fl

Frequency

ToCC)

Reference

1MHz

r.t.

— —

—

24 29 13

E33

10.3 6.7 5.818

7.8 6.3 5.154

25

Table 7. GaP0 4 Piezoelectric Constants (C/m2). qi 0.20 0.209 0.2238

ei4 0.03 0.107 0.1235

To(°C)

Reference

—

16 30 13

26 25

Table 7(a). First Order Temperature Coefficients of GaP0 4 Piezoelectric Constants (ppm/°C). ei4 -170.0

e

ll 49.52

T„(°C)

Reference

25

13

Table 8. GaP0 4 Elastic Constants (GPa).

«fl


66.7 70.7 66.58 ±0.37 67 66.36

-12.9 6.6 21.81 ±0.70 21

66.35 69.09

21.65 21.97


14.56 19.10

<1 E 4

-3.5 -17.8 3.91 ±0.33 -4 6.56 4.2 4.20 4.66

E C c

c

33 103.8 58.3 102.13 ±0.55 102 101.24

44 62.5 41.9 37.66 ±0.27 37 37.80

101.31 106.96

37.80 39.33

156

T„(°C)

Reference

39.8 32.1 22.38 ±0.32

— —

31 29 30

—

—

22.35

27 27 25 25?

4s

22.35 23.56

26°

16 15 15 13 32

New Piezoelectric

Substrates for SAW Devices

1023

Table 8(a). First Order Temperature Coefficients of G a P 0 4 Elastic Constants (ppm/°C).

•fl

<,E2

-37+1 -51.2

— -277 -242

«& —

—

-27.8

520

,E c 33 -118+10 -123.0

487

-54

<£

c

«fc

44

-— -4.4

-31+10 62.7 47.2

-147

-6.3

29

T„(°C)

Reference

—

29 33 33 15 15 14 14 32

26 26 27

-156

-63 -65 -17

-257.2 -143

-180 459.6

-135 -103.0

-62

69

200.4

825

-14.1

28.1

-44

414

-65

2

41

25 25?

Table 8(b). Second Order Temperature Coefficients of G a P 0 4 Elastic Constants (ppb/°C 2 ).

<E1 -47

«£ -123 -198

<E3 -37

<1E4 -196

CE

-51

°44 -40 9.4 -48

c33

350.4

-62

-34

-151

-88

-105

-1550 2000

-84

5

197

-243

-158

-497

320 -64

T„(°C)

Reference

26 26 25 27

33 33 33 15 15 14 3.2

«& -9.5 27.1 34.7

-12 -207

0

25?

Table 8(c). Third Order Temperature Coefficients of G a P 0 4 Elastic Constants (ppt/°C 3 ).

C,E1

85

4

283

<1E3 -121

«£

E C C33

C44

4e

TofC)

Reference

25

89

-13

-7

25?

32

The variations in the reported constants arise from three distinct sources: 1) limitations imposed by the quality of the measured data, 2) limitations in the data analysis, and 3) real variations in the quality and properties of the material samples. Material quality has been related to variations in the reported dielectric constants and all of the temperature coefficients,34 whereas measurement peculiarities have been related to variations in the reported piezoelectric constants. In particular, it has been observed that the piezoelectric constants appear to be underestimated.23 Measured values of BAW velocities for selected orientations are listed in Table 9. The differences between the various sets of measured velocities illustrate the magnitude of experimental errors in the underlying data. It is unclear which set of room temperature constants is "best". Detaint indicates a preference for the constants determined by Palmier for BAW calculations but provides no supporting data.34 In contrast, Briot demonstrates best agreement between calculations using the constants determined by Wallnofer and measured SAW data for Xaxis propagation on rotated Y-cuts.35 Perhaps less disagreement is found with respect to the "best" set of temperature coefficients. Detaint demonstrates best agreement between BAW calculations and measurements over a broad range of orientations using the temperature coefficients from Wallnofer,34 while other temperature coefficients provide

157

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J. A.

Kosinski

good results only near the AT-cut. Briot shows good agreement for SAW calculations using the temperature coefficients from Palmier near the AT-cut, but not for the Y-cut.35 Table 9. GaPQ4 BAW Wave Velocities (mis). Direction

Polarization

X X X Y Y Y Z Z (YXl)+45° (YXl)+45° (YXl)+45° (YXl)-45° (YXl)-45° (YXl)-45°

long fast shear slow shear long fast shear slow shear long shear long fast shear slow shear long fast shear slow shear

Ref. 30 T„ = 26°C 4352±3 3280±5 2440±7 4333±3 3228±9 2550±11 5348+2 3242.5±4.5 5051 3118 2766 5195

Ref. 36

—— — 4344 3220 2527 5344 3220

Ref. 15 r.t. 4337 3241 2417 4358 3228 2546 5327 3254

— 2779

Some caution is in order when reading the literature on gallium orthophosphate material constants. First, there are varying standards and sign conventions used by different authors. The magnitudes of the constants may be compared directly, but the sign of c14 is different between the convention used by Bechmann for quartz,37 and the recent IEEE standard.38 Second, the measurement conditions for the constants are not always specified. For example, many of the elastic constants are listed simply as "c" without clarification as to whether they are cE (required for calculations of device properties) or cD (measured from piezoelectrically stiffened BAW modes). Similarly, the dielectric constants are often not clearly presented as either s s or sT but simply as "e". Lastly, the reported values of temperature coefficients are only valid with respect to the specified reference temperature, and must be translated to a common reference temperature for any proper comparison. 2.5. Device properties Gallium orthophosphate displays good device characteristics in terms of large piezoelectric coupling and zero temperature coefficient of frequency orientations for both BAW and SAW. Calculated values for zero temperature coefficient orientations are listed in Table 10. Measured properties for BAW devices are listed in Table 11. Analagous to quartz, a gallium orthophosphate AT-cut exists in the vicinity of (YX1)-12.5° and a BTcut exists in the vicinity of (YXl)-79°.32'33 These data anticipate favorable STW characteristics near (YX1)77.5° with a zero temperature coefficient of frequency and piezoelectric coupling larger than that of STW on quartz. A number of temperature compensated SAW orientations have been calculated by Briot; these are listed in Table 12.35 Measured properties of SAW devices are listed in Table 13. The metallized-

158

New Piezoelectric

Substrates for SAW Devices

1025

unmetallized Rayleigh wave velocity difference for the ST-cut of gallium orthophosphate at u= 57° is nearly three times that of the ST-cut of quartz.33 Note that most data on GaP0 4 devices, including the data in Tables 10-13, are reported using IEEE 176-1987,38 wherein the AT-cut of quartz is at 9 = -35.25°. The reported values of the Qxf product are listed in Table 14. These are distinctly the lowest of the three candidate materials and are only 1% of that observed for quartz. Improved material growth with reduced OH content may lead to an increased Qxf product, but it is unclear whether the Qxf product of this material will ultimately meet or exceed that of quartz.

Table 10. GaP0 4 Calculated Zero Temperature Coefficient BAW Orientations. Mode shear shear shear shear

Orientation (YX1)-16° (YXl)-73.3° (YX1)-11.8° (YXl)-85°

Coupling 12.4%

— — "low"

Reference 33 33 32 32

Table 11. Measured Properties of Significant GaP0 4 BAW Orientations. Orientation (YX1)-17.4°

Polarization slow shear

(YX1)-16°

slow shear

(YX1)-15°

slow shear

Properties k=12.4% Turnover = 40.5°C Parabola constant = -18.28 ppb/°C2 k=12.4% Turnover = 25°C Parabola constant = -18 ppb/°C2 v=2548.2 m/s k=15.97%

Reference 16

33

20

T ^ = -2.39 ppm/°C (YX1)-12.5°

slow shear

v=2539.4 m/s k=15.98%

(YX1)-11.8°

slow shear

(YX1)-15.77°

slow shear

(YX1)-13.1°

slow shear

v=2540 m/s k=13% Turnover = 25°C Parabola constant = -10 ppb/°C2 v=2540 m/s k=13% Turnover = 25°C Parabola constant = -10 ppb/°C2 v = 2540 m/s k = 16.7%

19

T£> = 3.37 ppm/°C

fr

fr 3)

T^ =-100ppt/°C 3

159

32

34

2

1026 J. A. Kosinski Table 12. GaP04 Calculated Zero Temperature Coefficient SAW Orientations Featuring Zero Power Flow Angle. Orientation (YXwlt)0°,-25°,0° (YXwlt)10°,-35°,0° (YXwlt)20°,-45°,10° (YXwlt)30°,±50°,20° (YXwlt)40°,50°,10° (YXwlt)50°,40°,0° (YXwlt)-10°,-40°,0° (YXwlt)-50°,40°,0°

Velocity (m/s) 2360 2390 2440 2490 2450 2400 2400 2400

k2 (%) 0.30 0.30 0.24 0.20 0.30 0.30 0.30 0.30

Reference 35 35 35 35 35 35 35 35

Table 13. Measured Properties of Significant GaP04 SAW Orientations. Orientation \i. = 5T

Propagation X

Properties "ST-cut" k2 = 0.29%

Reference 33

T^ 2) = -50 ppb/°C2 Z-cut

^=15

(YX1)-15°<9<5°

X

k' = 0.06% Turnover = 75°C Parabola constant = -25 ppb/°C2 temperature compensated

15

35

Table 14. GaP04 Qxf Product. Type BAW BAW BAW

Direction (YX1)-12.5° (YX1)53° (YX1)-13.1°

Polarization slow shear slow shear slow shear

Frequency fa

f. fr

Qxf(xlO n ) 0.0064 0.0488 0.0375

Reference 19 33 2

3. Calcium Gallo-Germanates - Langasite, Langanite, and Langatate 3.1. General comments The calcium gallo-germanate family of materials has been the focus of intense development during the past decade. Materials belonging to this family have been found to possess moderately high piezoelectric coupling jointly with zero temperature coefficient of frequency orientations,39 and extremely low acoustic loss. Of highest interest for piezoelectric devices are langasite (lanthanum silicon gallate La3Ga5Si014), langanite (lanthanum niobium gallate La3Ga5 5Nbo50i4), and langatate (lanthanum tantalum gallate La3Ga5 5Ta0.5Oi4). These materials are a-quartz isotypes in that they belong to symmetry class 32. However, they are not a-quartz homeotypes and exhibit a completely different internal structure.41 It is particularly important to note that none of these three materials are proper single crystals.41 They are, instead, disordered structures wherein one of the cation sites is occupied either by gallium or respectively silicon,

160

New Piezoelectric

Substrates for SAW Devices

1027

niobium or tantalum. On a macroscopic level, the cation distribution in the shared site is 50:50 between the two species. However, on a microscopic level, the distribution from unit cell to unit cell is entirely random, and hence there are significant issues to be resolved in defining homogeneity and uniformity for these materials. The mythology of the calcium gallo-germanate family provides an interesting footnote to the history of the Cold War. These materials went largely unnoticed in the West until the presentation of two papers on langasite devices at the 1991 Frequency Control Symposium.24,27 To some, this represented the piezoelectric version of a Soviet "secret weapon" that had been deliberately hidden and hence triggered a "materials race" as the West rushed to catch up. In reality, however, the development of the calcium gallogermanates had not been hidden,41 and the article "A New Piezoelectric Material, Langasite (La3Ga5SiO!4), with a Zero Temperature Coefficient of the Elastic Vibration Frequency" by Andreev and Dubovik was readily available in the West. 3.2. Crystallography As quartz isotypes, langasite, langanite, and langatate belong to symmetry class 32, characterized by a single three-fold symmetry axis and three equivalent two-fold symmetry axes as illustrated in Fig. 1. However, unlike quartz, the three-fold axis is not a screw axis, resulting is a single form belonging to space group P321.44 The lack of handedness eliminates the possibility of optical (Brazil) twins, but electrical (Duaphine) twins remain possible. The internal structure of the calcium germano-gallates has been studied in detail.41 It should be noted that langasite differs from langanite and langatate with respect to the location of the disordered site. In the former, Ga and Si randomly occupy the 2d site featuring 4-fold oxygen coordination, while in the latter the Ga and Nb or Ta occupy the la site featuring 6-fold oxygen coordination. Measured values of lattice constants of langasite are listed in Table 15. There is a single formula weight per unit cell. Analysis of the data near room temperature lead to values of a=8.1685±0.0054A and c=5.0920±0.0100A at 25°C corresponding to an x-ray density of 5742.4±18.8 kg/m3 which is consistent with the previously reported values as listed in Table 16. Langasite thermal expansion data are listed in Table 17.

Table 15. LajGasSiOw Lattice Constants.

a (A)

c(A)

M°C)

Reference

8.162 8.162+0.005 8.168+0.003 8.16656 8.16787 8.1662 8.1783 8.1684±0.0001 8.1685+0.0054

5.087 5.087±0.005 5.095+0.001 5.0964 5.0970 5.074 5.1014 5.0975±0.0001 5.0920±0.0100

— — — — — —

44 41 41 45 45 46 47 48

25

this work

0 25

1028

J. A.

Kosinski Table 16. La3Ga5SiOi4 Mass Density. Mass Density (kg/mJ) 5754 5743 5737 5751 5764 5764 5742.4118.8

Method x-ray hydrostatic weighing measured x-ray

T„(°C)

— 17

— — —

— —

20 25

x-ray

Reference 41 49 50 51 52 53 this work

Table 17. La3Ga5SiOi4 Thermal Expansion.

a® (ppm/°C) 5.11 5.84 5.15 5.07 5.08 5.046

a\f (ppb/°C2)

a

3 3 (PPm/°C)

3.61 4.03 3.65 3.60 3.49 3.455

3.2

.... .... ....

—

4 f (ppb/°C2)

To(°C)

Reference

— 2.7

20 27

.... .... — —

20 25 20

54 55 56 57 58 53

....

Published data on the thermal stability of langasite are listed in Table 18. All of these compounds are phase stable up to their melting points at or above 1470°C. In consequence, devices fabricated using these materials may be processed or operated at significantly higher temperatures than comparable quartz devices. Table 18. La3Ga5SiOi4 Critical Temperatures. Reference 44 59

Melting Point (°C) 1470+20 1470

Transition Point (°C) None None

3.3. Crystal growth The calcium gallo-germanates of interest here are congruently melting compounds in the ternary oxide systems of La203-Ga203-Si02, La203-Ga203-Nb205, and La 2 0 3 -Ga 2 0 3 Ta 2 0 5 . The phase relations for langasite and langanite have been determined. ° The phase relations for langatate have not been determined, but are expected to be similar to those of langanite.50 The homogeneity range of these compounds is rather narrow. Congruently melting compounds are appropriate for melt growth techniques. To date, only the ,

• ,

I

^

j

x-

,,

e

1

v „ 39,41,44,47-49,51,59-68

x

v

Czochralski method has been reported for growth of langasite. Ine growth of langanite or langatate is largely similar to that of langasite, with small accomodations for the slightly higher melting points.65

162

New Piezoelectric

Substrates for SAW Devices

1029

Langasite crystals have been grown using several different types of pulling apparatus and feed materials synthesized by different methods. Langasite feed material is formed by solid phase synthesis (SPS) and melting of a mixture of the constituent oxides with an optional addition of metallic gallium,47'49' 59'64 or by a self-distributing high temperature synthesis (SHS) method.63 The purity of the starting materials has generally been reported qualitatively as "highly pure",49'59 however quantitative results typically describe ordinary 3N or 4N purity constituents.48'62"64 The feed mixtures are often provided with an excess of Ga 2 0 3 or La 2 0 3 in order to compensate for the volatility of these components. Seeds for initial growth have been formed by quenching on Pt wires. Z-axis growth has been reported most often,39'47'49'61,62'65'66 although X- and Y-axis growth are possible.39'49'61'62 The growth rate along the Z-axis is more than twice that of the Yaxis, which is in turn larger than that along the X-axis.49 Langasite has been grown using both Pt and Ir crucibles.39'44'47'63"65 Due to their slightly higher melting points, langanite and langatate are grown only in Ir crucibles.65 Crucibles are typically as tall as they are wide, and the width is chosen to be about one and one half times the diameter of the desired crystal. Langasite crystals typically have been grown both in air39'59 or in an inert gas ambient (N2 or Ar) with a small (1% - 4%) partial pressure of oxygen to suppress dissociation of the volatile oxide components, however growth in a pure N 2 ambient has been described recently.65'66 The choice of crucible material and growth ambient, along with the melt stoichiometry require a compromise. Pt crucibles are less susceptible to oxidation than Ir crucibles and hence allow a higher partial pressure of oxygen, but melt at substantially lower temperature leading to Pt inclusions in the as-grown crystals. Ir crucibles are more resistant to absorption into the melt, but are less resistant to oxidation and hence limit the allowable partial pressure of oxygen. The stoichiometry of the melt can be adjusted to obtain a slight excess of Ga 2 0 3 or La 2 0 3 in order to compensate for their volatility, with the required deviation from stoichiometry dependent upon the partial pressure of oxygen and vice-versa. It has been reported that the deviation from stoichiometry should remain small at less than 0.1% in order to avoid growth defects.47'59 Interestingly, in the single detailed analysis of the stoichiometry of an as-grown crystal, the observed deviation from stoichiometry was much larger than 0.1%: La 2 0 3 was 48.6% as-grown vice 48% ideal, Ga 2 0 3 was 48.9% as-grown vice 46.1% ideal, and Si0 2 was 3.1% as-grown vice 5.9% ideal.69 Reported crystal growth rates range from 1 mm/hr to 6 mm/hr, with general agreement on 1 mm/hr to 2 mm/hr as providing quality growth at an acceptable rate.39'41'48'49'60'63'65 The rotation rate depends upon the pulling rate, with rotation rates as high as 50 rpm being used for the highest growth rates as compared to 10 rpm at the lowest rotation rates. The allowable variation in rotation rate is rather small; a deviation of 1 rpm from ideal causes serious growth defects.48 All of the described pulling apparatus use RF heating, in most cases with an after heater. There is general agreement on the need to limit the temperature gradient above the melt in order to avoid cracking during growth, with specific recommendations to limit the gradient to less than 20°C/cm.48'63 All of the described pulling apparatus employ weight measurement as the independent variable for controlling the diameter of the crystal during growth. The most recent reports indicate improved crystal quality as a result of more sophisticated processing of the weight measurement.66 Observed growth defects in langasite crystals include twins, inclusions, block formation, cracking, and growth striations. Hot pyrophosphoric acid has been used as an

163

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J. A. Kosinski

etchant to reveal twins.6 Electrical twins occasionally have been observed in langasite, but more commonly are found in langanite and langatate.66 Inclusions have been associated with two sources, namely metallic Pt or Ir dissolved from the crucible into the melt, and other phases precipitated from the melt.47,61 Block formation and low angle growth defects have been associated with large temperature gradients in the growth process and hence may be controlled through suitable choice of growth parameters. Cracking has typically been associated with block formation due to the inherent thermal expansion mismatch between the differing growth regions. In some cases, bubble inclusions and microcracks have been observed along the central core of the crystal.39'47'61 Periodic growth striations have been reported widely.10'47'61'70 The striations are commonly associated with perturbations in the growth conditions such as temperature fluctuations in the melt. The color of langasite crystals ranges from nearly colorless to light yellow through amber to brown.48,49'59,61'62'65'71 The coloration results from an absorption band at 0.36 um to 0.41 urn. The coloration has been associated with Rh dissociated from either the crucible or the thermocouple used to measure the temperature of the melt.62 The coloration can be modified by sweeping and annealing.71 Charge compensation using Al doping eliminates the coloration and improves the acoustic properties.62 The perfection of as-grown langasite crystals has been studied by Raman spectroscopy,72 IR spectroscopy,62 X-ray diffraction,47'61,73 X-ray topography,10,70,74 and optical activity.73,75 The X-ray results are the most significant to date. X-ray diffraction has determined that the periodic growth striations commonly observed correspond to changes in the lattice constants on the order of Ac/c « 10"4 with a period of 35 um to 70 um.48,67,73 This implies a velocity inhomogeneity on the order of 50 ppm. Measured values for velocity homogeneity are substantially larger, on the order of 3000 ppm.69 Xray topography has demonstrated the significant effects of the growth striations on the vibrations of acoustic wave devices.10'74 3.4. Processing Reported values for the hardness of langasite are listed in Table 19. Langasite is significantly softer than quartz. Cutting has been reported using a slurry saw with SiC abrasive followed by lapping using 3 um and 1 um aluminum oxide abrasive.77 Mechanical polishing of langasite is best accomplished using colloidal silica.78 Chemical polishing yielding a 5 nm surface has been demonstrated using a 1:50:150 solution of HC1:HF:H20 at 70°C.78 Langasite is non-hydroscopic.59 Both acids and alkali may be used as solvents.10

Table 19. La3Ga;SiOi4 Hardness. Mohs 6.5-7 5.5 6.6

Vickers (GPa)

—

10

— ——

Reference 39 51 76 79

New Piezoelectric

Substrates for SAW Devices

1031

3.5. Material properties oflangasite Many of the comments concerning the material properties of gallium orthophosphate apply equally to the calcium germano-gallates. The form of the elasto-piezo-dielectric constants matrices (augmented by the entropy-temperature relations) for symmetry class 32 is shown in Fig. 1. Reported values for the linear dielectric, piezoelectric, and elastic constants and their temperature coefficients for langasite are listed in Tables 20 and 21, 22, and 23 respectively. The dielectric constant data are separated into different tables for eT and e s . The reported values of the elastic and piezoelectric constants have been obtained from pulse-echo and resonator method measurements, inclusive of SAW device measurements. Reported values for various nonlinear material constants are presented in Tables 24-27.

Table 20. La3Ga5SiOi4 Relative Dielectric Permittivities at Constant Traction.

E E

T

ll 18.99 20+1 18.86 18.89 18.89 18.97 19.06 19.05 18.96

ET

Frequency

T„(°C)

Reference

1kHz 1kHz

17

—

80 81 55 69 82 57 58 53 this work

E33

49.32 48±2 49.10 49.0 49.3 52.00 51.60 51.81 50.19

27 20 20 20. 25 20 25

— — — 1 kHz

— — —

Table 20(a). First Order Temperature Coefficients of LajGasSiOn Dielectric Permittivities at Constant Traction (ppm/°C). ET

ET E

ll 447 153 153 137 135.5 134.5

T„(°C)

Reference

27 r.t. 20 20 25 20

55 54 69 57 58 53

E

33 -618 -760 -760 -795 -783.4 -787.0

Table 20(b). Second Order Temperature Coefficients of La3Ga5SiO,4 Dielectric Permittivities at Constant Traction (ppb/°C2).

E E

T

ll -2490 82 118.0 118.0

E

33 -66.8 1076 661.2 658.6

T„(°C)

Reference

27 20 25 20

55 57 58 53

165

1032

J. A.

Kosinski Table 21. La3Ga5SiOi4 Relative Dielectric Permittivities at Constant Strain.

«?1 18.87 18.97 18.92 18.92 18.92

£33

49.32 49.24 50.701 50.7 50.19

To(°C)

Reference

17

80 56 83 84 this work

— — 20 25

Table 21(a). First Order Temperature Coefficients of La3Ga5SiOi Dielectric Permittivities at Constant Strain (ppm/°C).

E8

T

ll

150

ET

E33 -772.5

T„(°C)

Reference

20

84

Table 22. La3Ga5SiOi4 Piezoelectric Constants (C/m2). en -0.45 0.45 -0.44 -0.45 -0.44 -0.41 -0.431 -0.44 -0.438 -0.4371 -0.461

en 0.077 -0.07 0.07 0.077 -0.08 0.08 0.108 -0.08 0.104 0.1039 0.257

TofC)

Reference

17

80 40 55 56 83 69 57 84 58 53 this work

— 27

— — 20 20 20 25 20 25

Table 22(a). First Order Temperature Coefficients of La3Ga5SiOu Piezoelectric Constants (ppm/°C). eil -2400 456 587.5 587 464.5 469.8

ei4 -5000 -628 625 625 -700.3 -713.8

T„(°C)

Reference

27 20 20

55 57 84 85 58 53

— 25 20

Table 22(b). Second Order Temperature Coefficients of La3Ga5SiOi4 Piezoelectric Constants (ppb/°C2). eil 1032 -427.5 -428.5

ej4 1480 1600 1594

T0(°C)

Reference

20 25 20

57 58 53

166

New Piezoelectric

Substrates for SAW Devices

1033

Table 23. La,Ga 5 SiOi 4 Elastic Constants (GPa).

<1E1

&

190.9 191 190.2 ±1.3 190.2 188.9 190.2 188.75 190.1 189.3 188.75 189 188.9 189.75

106.3 106.3 106.3 +2.6 106.3 104.6 106.3 104.75 103.0 105.0

— 104 104.2 104.95

«f3

104.2 104.2 91.9 ±3.7 99.39 96.8 91.9 95.89 95.24 95.28 95.89 102 101.5 96.12

& 15.2 15.6 14.7 +1.4 14.70 14.3 14.7 -14.12 15.7 14.93 -14.12 14.4 14.42 13.84

cCE 33 261.9 261.9 262.1 ±0.6 262.1 262.2 261.4 268.3 262.4 261.4 268 268.3 261.68

<4E4 52.4 52.4 53.82 ±0.40 53.82 53.9 53.4 53.5 53.31 53.84 53.5 53.3 53.30 53.07

To(°C)

Reference

17

80 40 54

«& 43.2 43.2 42.0 ±1.3 41.98 42.2 42.35

42 43.5 42.16

42 42.4 42.37 42.40

.... r.t.

20 27

.... .... 20 20. 20 25 20 25

54 55 56 83 69 57 84 58 53 this work

Table 23(a). First Order Temperature Coefficients of La3Ga5SiOi4 Elastic Constants (ppm/°C).


<&

-58.7 -47 -52.7 -53 -66.3 -64.1 -53 -58.4 -57.54

-218 -100 -107.4 -92

— — -85 -98.7 -98.15

E cC

13 -101 -130 -14.4 -88 -75 -75 -100 -82.3 -81.61

<E4 -154 -370 -176 -205 -334.8 -350.9 -310 -307.0 -307.5

E cC

33 -135 -94 -105 -104 -94.1 -91 -94 -105.0 -104.0

<4E4 -79.7

-30 -57.6

-62

4

139 36 12

ToCC)

Reference

27

55 54 69 57 85 85 86 58 53

r.t.

20 20

-62.8 -58.7

-4.7 -13.46 -13.69

-55

—

.... .... —

-58.7 -57.39

-8.77 -7.576

25 20

Table 23(b). Second Order Temperature Coefficients of La3Ga5SiOi4 Elastic Constants (ppb/°C2).

<E1 -113 -55.4 -4.2 -82.7 -82.65

E C C33

«f2

«?3

<1E4

1085 48.1 25 -51.9 -51.83

-117 156.8 -131 -68.1 -68.10

452

65

44 102

-10.4

-62.8 -109 -89.7 -89.61

-133 -111 -103.6 -130.5

870 95.5 95.34

c

4

-1564 -178 -40.7 -119.4 -119.4

T„(°C)

Reference

27 20 20 25 20

55 69 57 58 53

Table 24. La 3 Ga 5 SiO H Nonlinear Dielectric Permittivities at Constant Strain (10"2" F/V). T„(°C)

Reference

20

84

E

lll -0.5

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J. A.

Kosinski \ Table 25. La3Ga5SiOi4 Nonlinear Piezoelectric Constants (C/m2).

e

e

l 11 9.3

e

eil4 1.0

l 13 -3.5

122 0.7

e

ei34 6.9

ei24 -4.8

e

144 -1.7

315 -4

To(°C)

Reference

20

84

Table 26. La3Ga5SiOu Electrostriction Constants (10"' N/V2). Hll -26

Hi 4 -43

Hl3 20

Hl2 65

H31 -24

H41 -170

H33 -40

H44

T„(°C)

Reference

-44

20

84

Table 27. La3Ga5SiO,4 Third Order Elastic Constants (GPa). E C c

l 11 -972

E C c

l 12

7

E C c

l 13 -116

E C c

114 -22

E C c

123

9

CE c

124 -28

C cE 133

-721

To(°C)

Reference

20

84

Table 27. (cont.) La^GasSiOu Third Order Elastic Constants (GPa). E cC

134 -41

E cC

144 -40

CE c

155 -198

E cC

222 -965

CE

C333 -1834

E cC

344 -389

CE C444

202

T„(°C)

Reference

20

84

The reported values of the dielectric constants vary as much as 8%, the reported piezoelectric constants vary as much as 37%, and the reported elastic constants vary between 1% and 12%. Larger variations are observed in the reported temperature coefficients. As with gallium orthophosphate, the variations in the reported material constants arise from three distinct sources: 1) limitations imposed by the quality of the measured data, 2) limitations in the data analysis, and 3) real variations in the quality and properties of the material samples. Material quality has been related to variations in the reported dielectric and piezoelectric constants, and all of the temperature coefficients. Variations in reported piezoelectric constants additionally have been related to intrinsic difficulties of measurement.34 An extensive data set exists for the measured values of BAW velocities and their temperature coefficients for selected orientations as listed in Tables 28 and 29. The differences between the various sets of measured velocities illustrate the magnitude of experimental errors in the underlying data used to derive the elastic constants and in some cases the piezoelectric constants. The values for the material constants listed in the tables are as reported in the literature. The same cautions are in order regarding the material constants of the calcium gallo-germanates as for those of gallium orthophosphate. Unlike the case of gallium orthophosphate, most of the data on the calcium gallo-germanates has been reported using the IRE-1949 convention.37 The magnitudes of the constants obtained using the different standards may be compared directly, but the sign of c14 is different between the convention used by Bechmann for quartz and the recent IEEE standard.37'38 Additional confusion arises with respect to the sign of the piezoelectric constants. Second, the measurement conditions for the constants are not always specified. For example, many of

168

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the elastic constants are listed simply as "c" without clarification as to whether they are cE (required for calculations of device properties) or cD (measured from piezoelectrically stiffened BAW modes). Similarly, the dielectric constants are not always clearly presented as either e s or sT. Lastly, the reported values of temperature coefficients are only valid with respect to the specified reference temperature, and must be translated to a common reference temperature for any proper comparison.

Table 28. La3Ga5SiOu BAW Wave Velocities (m/s). Orientation X-cut X-cut X-cut Y-cut Y-cut Y-cut Z-cut Z-cut (YXl)+45° (YXl)+45° (YXl)+45° (YXl)-45° (YX!)-45° (YXl)-45°

Polarization long fast shear slow shear long fast shear slow shear long shear long fastshear slow shear long fast shear slow shear

Ref. 83 5752.8 3311.7 2379.9 5754.9 3010.7 2738.8 6749.4 3053.6 5965.7 3283.3 3232.2 6313 3333.6 2431.4

Ref. 80 5784 3344 2344 5792 2971 2767 6753 3021 5998 3323 3141

Ref. 57 5753 3317 2370 5762 3016 2742 6753 3059 5985 3291 3228

Ref. 69 5746 3305 2394 5756 3003 2750 6826 3043 5949 3281

Ref. 55 5748 2380 5754 3015 2745 6750 3061

Ref. 40 5784 3344 2344 5792 2971 2277 6753 3021

3325 2427

Table 28. (cont.) La3Ga5SiOu BAW Wave Velocities (m/s). Orientation

Polarization

Ref. 89

Ref. 88

Ref. 87

X-cut X-cut X-cut Y-cut Y-cut Y-cut

long fast shear slow shear long fast shear slow shear

5748.7 3311.5 2379.6 5755.3 3009.9 2738.0

578x±10 331x±10 234x±10 579x

578x+10

277x±10

277x±10

Z-cut Z-cut (YXl)+45° (YXl)+45° (YXl)+45° (YXl)-45° (YXl)-45° (YXl)-45°

long shear quasi-long quasi-shear pure shear long fast shear slow shear

6746.7 3052.2

675x+10 301x±10

675x±10

169

579x+10

Ref. 2 Table 6

5769 3005 2775

Ref. 80 Table 7 5769

Ref. 82

2760 2764

276x

578x

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J. A.

Kosinski Table 28. (cont.) La3Ga5Si014 BAW Wave Velocities (mis).

Orientation

Polarization

X-cut X-cut X-cut Y-cut Y-cut Y-cut Z-cut Z-cut (YXl)+45° (YXl)+45° (YXl)+45° (YXl)-45° (YXl)-45° (YXl)-45°

long fast shear slow shear long fast shear slow shear long shear quasi-long quasi-shear pure shear long fast shear slow shear

Ref. 80 N. 5784

Ref. 52

Ref. 2 Table 5

Ref. 74 Table 2

Ref. 71

Ref. 51

2764

2762

2753

2754

2767

2760

Table 29(a). First Order Temperature Coefficients of La3Ga5SiOi4 BAW Wave Velocities (ppm/°C). Type

Direction

Polarization

BAW BAW BAW BAW BAW BAW BAW BAW BAW BAW BAW

X X X Y Y Y Z Z (YXl)+45° (YXl)+45° (YXl)+45°

long fast shear slow shear long fast shear slow shear long shear long quasi-shear pure shear

Ref. 69 T() = 20°C -24.9 -53.2 49.8 -31.0 -18.8 6.6 -50.0 -26.5 -35.1 -52.2

Ref. 57 To = 20°C -17 -50 +50 -32 -17 15 -45 -24 -29 -23 -50

Ref. 89 T„ = ??°C -21.3 -43.7 53.5 -29.9 -14.1 13.6 -40.3 -27.8

Table 29(b). Second Order Temperature Coefficients of La3Ga5SiO,4 BAW Wave Velocities (ppb/°C2). Type

Direction

Polarization

BAW BAW BAW BAW BAW BAW BAW BAW BAW BAW BAW

X X X Y Y Y Z Z +45°YZ +45°YZ +45°YZ

long fast shear slow shear long fast shear slow shear long shear long quasi-shear pure shear

Ref. 69 To = 20°C -24.7 -39.1 -131.0 -42.0 -57.5 -89.0 -29.2 -64.9 -31.2 -87.0

Ref. 57 T„ = 20°C -2.3 -110 -57 -64 -39 -40 -50 -50 -17 -67 -29

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Substrates for SAW Devices

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3.6. "Best" material constants for langasite As seen from the time progression of the reported values of the material constants and their temperature coefficients, the reported values appear to be converging toward a "best" set of material constants. Briot demonstrates very good agreement between calculations of room temperature behavior using material constants from Sakharov57 and experimental data for SAW propagation on Z-cut langasite, but poor agreement for the temperature behavior.90 The observed temperature behavior was bracketed by that calculated using two sets of temperature constants from Silvestrova.54,69,90 More recent results for Y+45°, Y+50°, and Y+55° rotated Y-cuts confirm the good room temperature agreement using material constants from Sakharov.57 These results also obtain a reasonable agreement between temperature behavior calculated using the earlier temperature coefficients from Silvestrova54 and the measurements.91 Similar good agreement was shown by Inoue between calculations of room temperature behavior using material constants from Sakharov57 and experimental data for SAW propagation on Xcut, Y-cut, and 50° rotated Y-cut langasite,92 also with poor agreement for the temperature behavior. An even better agreement has been shown by Kadota93 and Naumenko86 between room temperature calculations using material constants from Ilyaev55 and experimental data for LSAW and LPSAW propagation on rotated Y-cut langasite. However, the temperature coefficients of both Sakharov57 and Ilyaev55 provided poor agreement for the temperature behavior observed by Kadota; the experimental results for the orientation with a zero temperature coefficient of frequency at room temperature were bracketed by the calculated values.93 An ad hoc set of temperature coefficients developed by Naumenko was shown to provide good agreement for the temperature behavior of the Y-46.5° rotated Y-cut substrate. 86 Constants and temperature coefficients presented by Bungo53'58 demonstrate exceptional agreement between calculations and measurements of all SAW properties for the 50° rotated Y-cut of langasite. It is clear that the room temperature values of the material constants are close to those of Ilyaev,55 Sakharov,57 Sorokin,84 and Bungo,53,58 with the largest uncertainties in the dielectric and piezoelectric constants. The values of the temperature coefficients are likely close to those reported by Bungo.53,58 The aggregate of the measured values of bulk wave velocities listed in Table 28 provides a "best" set of measurement data for BAW propagation. This data, in conjunction with the aggregated dielectric constant and lattice constant data, may be used to determine a "best" set of material constants more accurate than those of any single experiment. Such values are listed in the tables as "this work". The listed values should predict wave velocities to better than 0.5% for most orientations, with the errors highest at orientations near 0=±45°. 3.7. Material constants for langanite and langatate There have been two measurements of the material constants of langanite,94,95 and one complete measurement of the material constants of langatate.96 These results are consolidated in Appendices A and B respectively. Calculations using these values have been generally in good agreement with measurements of devices using these materials.77,97 Langanite and langatate both feature larger piezoelectric coupling than langasite, with langatate the larger of the two. Both of these materials also feature zero

171

1038

J. A. Kosinski

temperature coefficient of frequency orientations, however device development using these materials has only recently begun.77'97 3.8. Langasite device properties Langasite displays good device characteristics in terms of large piezoelectric coupling and zero temperature coefficient of frequency orientations for both BAW and SAW. The calculated zero temperature coefficient BAW orientations are summarized in Table 30. The orientations of greatest interest to date for BAW are near the Y-cut, which features a zero temperature coefficient near room temperature jointly with nearly maximum piezoelectric coupling for the slow thickness shear mode. Measured properties for BAW devices are listed in Table 31. These data anticipate favorable STW characteristics near the Z-cut with a zero temperature coefficient of frequency and piezoelectric coupling larger than that of STW on quartz.

Table 30. La3Ga5SiOi4 Calculated Zero Temperature Coefficient BAW Orientations. Mode long long long long fast shear fast shear fast shear fast shear fast shear fast shear fast shear fast shear slow shear slow shear slow shear slow shear slow shear slow shear slow shear slow shear slow shear slow shear slow shear slow shear slow shear slow shear slow shear

Ti f(r D _- 0u

T«=0

TP=O ft

42Ko

k (%)

Ref.

(YX1)-61.8° (YX1)9.7° (YXwl)30°,±47.0° (YXwl)30°,±28.4°

0 0 1 4 3 0 0 0 0 0 4 5 7 17 17 3 17 3

55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 76 76 76 76 76 76 51 51 98

(YX1)53.7° (YXl)-85.5° (YXI)-45.6° (YX1)9.4° (YX1)36.1° (YXwl)30°,+85.7° (YXwl)30°,+41.0° (YXwl)30°,±24.3° (YXl)-47.6° (YX1)-12.7° (YX1)1.7° (YXwl)30°,±47.9° (YXl)-0.9° (YXwI)30°,±48.3° (YXl)-48° (YX1)-12.5° (YX1)0° (YX1)45° (YX1)0° (YX1)36°

— — .... — .... — 15 15 14.8

(YXl)-84° (YX1)6° (YX1)3°

172

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Table 31. Measured Properties of Significant La3Ga5SiOi4 BAW Orientations. Orientation (YX1)1.5°

Polarization slow shear

Y-cut

slow shear

Properties v = 2760 m/s k=15% "Optimum for temperature-induced frequency excursion over the range -60°C to +85°C" v = 2762 m/s k = 14.8% Tl f(r l ) _- 00

Reference 51

52

T^r2) = -63 ppb/°C2 T ® = -26 pptTC3 Y-cut

slow shear

Y-cut

slow shear

T„ = 25°C Turnover = 68.7°C Parabola constant = -68.9 ppb/°C2 Turnover = 64.7°C Parabola constant = -66.2 ppb/°C2

77 97 from N=3,5,7,9 data

A variety of temperature compensated SAW orientations have been reported recently for langasite,86 these are listed in Table 32. Reported properties of SAW devices are listed in Table 33. The orientations of greatest interest to date for SAW are near the 50° rotated Y-cut. One of the most interesting properties of the calcium gallo-germanates is an anticipated high intrinsic Q based on extremely low measured values of acoustic attenuation as listed in Tables 36 and 37. The reported values of the Qxf product for langasite, langanite, and langatate are listed in Table 38. The observed device Q of langasite has been somewhat less than anticipated. However, langanite and langatate have readily yielded Q values close to or greater than the maximum possible Q for the Xpolarized shear mode in quartz.77'97 It has been suggested that the disordered nature of these crystals limits the achievable material Q, and the development of fully ordered crystals with a calcium gallo-germanate structure has been recommended.67

Table 32. LasGasSiO^ Calculated Zero Temperature Coefficient SAW Orientations. Orientation (90°,90o,25°) (0°,140o,25°) (ZXtw)95°,26° X-prop. (ZXtw)25°,53° X-prop. (0°,154°,24°) (5°,150o,29°) (10°,150°,34°) (5°,145°,29°) (0°,140°,25.5°) (0°,138.5°,26.3°)

Properties Zero TCD Zero TCF Zero TCD Zero TCD TCF = 7 ppm/°C TCF = 3 ppm/°C TCF = -lppm/°C TCF = -2 ppm/°C TCF = 1 ppmTC TCF = 1 ppm/°C

Velocity (m/s)

k' (%)

2765 2798 2829 2793 2747 2743

0.35 0.18 0.183 0.51 0.50 0.47 0.42 0.37 0.34

173

Reference 99 92 84 84 86 86 86 86 86 86

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J. A.

Kosinski Table 33. Measured Properties of Significant La3Ga5SiOi4 SAW Orientations.

Orientation (90°,0 o ,-6°) (90°,90 o ,0°) (90°,90 o ,25°) X-cut (0°,90°,0°) Y-cut (0°,140°,22.5°) 50° rotated Y-cut (0°,142°,24.5°) (0°,143 o ,24°) (0°,140°,24°)

k 2 (%) 0.477 0.355

Reference 59 59 99

0.35

92

2742.1

0.32

92

2754

0.41

93

2756

0.42

93

Velocity (m/s) 2382.8 2287.82

Properties

zero T C D TCD = -42 ppm/°C T„ = 39°C TCF(2) = -52 ppm/°C 2 TCF=1.83ppm/°C PFA=0 TCF=1.63ppm/°C PFA = 0 To=28.8C TCF(2)=-67ppb/°C2

53

Table 36. La3Ga5SiOi4 BAW Acoustic Attenuation. Direction X

Polarization long

X X Y

fs ss long

Y

shear

Z

long

z

shear

Ref. 82 0.26 dB/cm @ 500 MHz

Ref. 40 0.5 dB/cm @ 900 MHz

Ref. 87 0.52±0.04 dB/(us GHz 2 ) @ 1 GHz

0.75+0.05 dB/(us GHz 2 ) @ 1 GHz 1.05±0.05 dB/(ns GHz 2 ) @lGHz

0.44 dB/cm @ 500 MHz

1.9 dB/cm @ 900 MHz

Ref. 59 0.8 B cm"' GHz 2 '"'88.8 MHz

Ref. 88 0.52+0.05

1.31 0.71 1.30

0.8 B cm - ' GHz 2 r'*88.8 MHz

0.85

0.75

1.30+0.04 dB/(us GHz 2 ) @lGHz

1.05

Table 37. La3Ga5SiOi4 SAW Acoustic Attenuation. Orientation Y' X'

59 0.8 B c m - G H z z @ 8 8 . 8 MHz 0.8 B cm"' G H z ' @ 88.8 MHz

Propagation X Y

Table 38. BAW Qxf Product for Selected Calcium Gallo-germanates. Material

Orientation

Polarization

Frequency

La 3 Ga 5 Si0 1 4 La 3 Ga 5 SiOi4 La 3 Ga 5 SiOi4 La 3 Ga 5 SiOi4 La 3 Ga 5 SiOi4 La 3 Ga5SiOi4 La 3 Ga 5 5 Nbo50i4 La3Ga5.5Tao5Oi4

Y-cut Y-cut Y-cut Y-cut Y-cut Y-cut Y-cut Y-cut

slow slow slow slow slow slow slow slow

fa f, fa fr fr

shear shear shear shear shear shear shear shear

174

fr fr fr

Qxf(xl0") 0.983 1.65 1.81 1.34 1.29 2.1 2.15 2.92

Reference 10 2 74 77 97 100 97 77

New Piezoelectric

Substrates for SAW Devices

1041

4. Lithium Compounds - Diomignite 4.1. General comments Lithium niobate, and to a lesser extent, lithium tantalate, have achieved prominence as piezoelectric materials featuring higher piezoelectric coupling than quartz. Both are limited, however, by a lack of temperature compensation. More recently, diomignite (tetragonal Li2B407) has been developed as an alternative material also featuring piezoelectric coupling significantly higher than quartz. This new material exhibits temperature compensated orientations for both bulk and surface waves, and has demonstrated high intrinsic material Q. Tetragonal Li 2 B 4 0 7 is best known as lithium tetraborate. It has alternatively been designated lithium borate, lithium diborate, and dilithium tetraborate, and has been abbreviated as either LBO or DLTB. The mineral name diomignite was approved by the Commission on New Minerals and Mineral Names, International Mineralogical Association in 1987 following identification of natural diomignite crystals in pegmatitie.101102 The name derives from the Greek dios mignen for "divine mix." 4.2. Crystallography Diomignite belongs to space group I4,cd within tetragonal symmetry class 4mm,103104 characterized by a single four-fold symmetry axis and two equivalent mirror planes as illustrated in Fig. 3.4 As with class 3m, the mirror plane symmetry causes all class 4mm materials to be pyroelectric. Diomignite lacks handedness, eliminating the possibility of optical (Brazil) twins. Electrical (Duaphine) twins remain possible. The internal structure of the diomignite has been studied in detail.103105106 Measured values of lattice constants of diomignite are listed in Table 39. There are eight formula weight per unit cell. Analysis of the data near room temperature lead to values of a=9.4746±0.007lA and c=10.2867±0.0192A at 25°C corresponding to an x-ray density of 2433.0±8.1 kg/m3 which is consistent with the previously reported values as listed in Table 40. Diomignite thermal expansion data are listed in Table 41. Sk,

Ek

AT

: : : : T

y,x2

6 3 2 2 1

• Di XfX]

AS

•-• •-•

V:

« . . . • « . . . •

• • • •

Fig.3. Class 4mm symmetry elements and matrices for equilibrium properties.'1

175

• •

J. 15

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J. A.

Kosinski Table 39. Li 2 B 4 0 7 Lattice Constants.

a (A)

c(A)

T„(°C)

9.47 9.479±0.003 9.477±0.005 9.475 9.49 9.47 9.4570±0.00025 9.479±0.003 9.479±0.010 9.474±0.006 9.477 9.477 9.47±0.03 9.4795 9.4757±0.0002 9.4794 9.470±0.004 9.464±10.003 9.4746±0.0071

10.26 10.280±0.004 10.286±0.006 10.283 10.30 10.26 10.28590±0.00020 10.290±0.004 10.340±0.007 10.297±0.006 10.286 10.296 10.26±0.08 10.312 10.2850±0.0002 10.2850 10.279±0.005 10.275±10.004 10.2867±0.0192

.... .... .... .... — 20

— 25 25

— — — r.t. 7

.... .... 25

Reference 103 105 107 108 109 110 111 106 112 112 113 114 115 116 117 118 102 102 this work

Table 40. Li2B407 Mass Density. Mass Density (kg/mJ) 244x 243x 244x 2451 245x 2420 2440 2439 2450 2433±1 2430±10 2436±4 2440 2439 2424 2431 2432 2437 2441 2433.0±8.1

Method x-ray x-ray measured measured x-ray measured measured measured measured x-ray x-ray measured measured x-ray x-ray measured x-ray x-ray x-ray

176

To(°C)

— — — — — — — — — 20 18 18

— r.t. r.t. 25 25

— — 25

Reference 103 107 107 104 108 119 119 109 110 120 112 112 121 122 116 123 123 102 102 this work

New Piezoelectric

Substrates for SAW Devices

1043

Table 41. U2B4O7 Thermal Expansion.

aj 1 / (ppm/°C)

a(f (ppb/°C2)

a^j (ppm/°C)

ag) (ppb/°C2)

13 13.0 11.1 12.5 5.1(1) 19.8(8) 12.7(5)

— —

«4 -1.5 -3.74 -2.5 -2.3(1) -1.62(9) -5.3(5)

— —

5.6

— — — —-

T„(°C)

Reference

—

108 124 125 110 120 112 126

20 25 25 20 25 22

20.8

— — — ....

Published data on the thermal stability of diomignite are listed in Table 42. There is no disagreement with respect to the stability of diomignite in terms of both phase transitions and melting point. Diomignite devices may be processed or operated at significantly higher temperatures than comparable quartz devices.

Table 42. Li2B407 Critical Temperatures. Transition Point (°C) None

Melting Point (°C) 917+2

Reference 127

4.3. Crystal growth Diomignite is a congruently melting compound in the binary oxide system of Li 2 0B 2 0 3 , 127 and appears alternatively as a phase within the ternary oxide system Li 2 0-B 2 0 3 Si0 2 The phase relations for the former system have been determined in detail,127128 the latter only approximately.129 Congruently melting compounds are typically synthesized using melt growth techniques; diomignite has been grown using both Czochralski and Bridgman methods. Interestingly, diomignite also has been grown hydrothermally. Feed material for melt growth may be synthesized by reaction of lithium carbonate and boric acid or boron trioxide,107,113,114'130"133 by reaction of lithium hydroxide and boric acid, or by reaction of lithium nitrate and boron trioxide.131 Alternatively, Li 2 B 4 0 7 powders are available in grades ranging from 99.9% to 99.999% purity. 131 ' 108 ' 1H 119'135'136> 137 Starting materials for hydrothermal growth are boric acid plus either lithium borate or lithium hydroxide, with HC0 2 H as the mineralizer.115 Diomignite crystals have been grown by the Czochralski method using either ^119,133-136,138,139 o r r e s i s t a n c e heating.113.114.137.140 Platinum crucibles are used nearly universally, with all recent growth in an air ambient.114,121132,137140 Crucibles are typically as tall as they are wide, and the width is chosen to be about one and one half times the diameter of the desired crystal. The feed mixtures are typically stoichiometric,121'135137139" 141 although a slight excess of boron sometimes is provided.114,119131 Seeds for initial growth have been formed by quenching on Pt wires. Diomignite crystals have been grown commonly along both X- and Z-axes.108,113,114,119'131-132-137,140-144 Growth also has been demonstrated along the [110] direction;135'139144 such boules simplify the manufacture of desirable 45° rotated X-cut devices.

177

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Kosinski

Reported Czochralski growth rates range from 0.13 mm/hr to 5 mm/hr, with general agreement on higher quality growth at slower growth rates (<0.5 mm/hr).108113'114119-131132'134-140144-146 The rotation rate is adjusted to achieve a flat or slightly concave solid-liquid interface, and is typically on the order of only a few rpm due to the high viscosity (1.5 poise) of the melt.108'1,3'114'119>,31-14°'144-146 There is general agreement on the need for a large temperature gradient on the order of 200°C/cm at the melt surface,113114133'135 and the need also to limit the temperature gradient to on the order of 10°C/cm in the cooling zone above the meit.108.U4133-135.137 Heat shields and/or after heaters have been used to establish the required thermal profile.119135137138 Many of the described pulling apparatus employ weight measurement as the independent variable for controlling the diameter of the crystal during growth,119135139 with substantial improvements in crystal quality attributed to the controlled growth regime.119 Nearly flawless crystals have been grown using an alternative control scheme based on measuring the instantaneous electrical current and hence torque developed by the motor driving the pulling rod.137 The inherent advantages of the latter method appear unappreciated. For the weight control technique with 0.0lg sensitivity as reported, at 1 mm/hr growth rate there is a distinguishable control readings every three to four seconds. In contrast, the torque control technique provides distinguishable control readings at the sampling rate of the current sensor. Hence, the time constant of the torque control system can be orders of magnitude faster than that of the weight control system. Diomignite crystals have been reported exclusively as clear and colorless. The main growth defects observed in diomignite crystals grown by the Czochralski method are coring and cracking,108'114'119''31'132'134'135'139'142'147 and occasionally inclusions,119'131'139 and voids.108135139 These defects have been related primarily to growth parameters such as pulling rate and rotation rate, but also to temperature fluctuations in the melt.132'147 The incidence of defects may be reduced by the use of higher purity starting materials.119'134137 Hot water'35 or glycerine and water114 have been used as etchants to evaluate crystal quality. Defect densities of 2000/cm2 to 9000/cm2 have been observed, typically screw or edge dislocations.135148 The viability of Czochralski grown diomignite wafers for mass production has been demonstrated via 200 ppm to 500 ppm wafer-towafer consistency and single wafer uniformity of the SAW velocity. Bridgman growth using both vertical and horizontal adaptations has been reported in detail.149"159 Both platinum149157 and graphite152153 vessels have been used for Bridgman growth. The starting materials reported for Bridgman growth have been limited to 99.9% or 99.99% purity,149151'157 with less precise control of stoichiometry and/or excessive water content.149150'151 Crystals have been grown from X-axis, Z-axis, and 45° rotated X-cut seeds.149150157'158 Growth rates below 3 mm/hr are required for high quality growth.149154 Many of the same defects observed in crystals grown by the Czochralski method have been observed in crystals grown by the Bridgman method: cracks and cores,149 dislocations,156 and microcracks.159 A 25% acetic acid etch has been used to reveal defects in Bridgman grown crystals;150'156 the most significant defects have been electrical twins to an extent not reported in Czochralski grown crystals. The quality of the as-grown crystals has been related directly to the purity of the starting materials, and the stability of the power supply and hence temperature profile during crystal growth.156159 The hydrothermal growth of diomignite crystals has been investigated systematically.115129160 Crystals have been grown in autoclaves with teflon liners, at 250°C and 100 bar. Various combinations of mineralizers and starting materials have been considered, with detailed results obtained for the relationships between crystal

178

New Piezoelectric

Substrates for SA W Devices

1045

growth rate, morphology, and growth conditions. Crystals as large as 12 mm x 12 mm x 10 mm have been obtained. The perfection and properties of as-grown diomignite crystals have been studied by ultrasound,112'161"163 Raman spectroscopy,144164 X-ray diffraction,111112117143 luminescence spectrometry,141 optical extinction,132 reflection spectrometry,165166 dilatometry,126 acoustic emission spectroscopy,167 thermal analysis,168 and synchrotron radiation.148 Absorption bands at 3550 nm, 4100 nm, and 4690 nm have been identified with disruptions in crystal stoichiometry and excess water content.141 Several studies observed anomalies at low temperatures possibly associated with phase transitions stimulated by thermal cycling,111'117'126'143'161'162'168 however these results are not consistent and thus far are not clearly explained. The results of Raman spectroscopy studies are in agreement that high temperature phase transitions cannot be ruled out theoretically, but are unlikely to be observed in practice.144'

4.4. Processing Reported values for the hardness of diomignite are listed in Table 43. Diomignite is significantly softer than quartz. Lapping has been reported using a cast iron plate with a SiC slurry. Mechanical polishing has been reported using a polyurethane foam sheet with a colloidal silica slurry.133 Diomignite is insoluble in organic solvents such as acetone or alcohol,108134 and etches slightly in deionized water or alkaline solutions. It is easily soluble in almost all acids,108134'169 In consequence, standard SAW device fabrication techniques using acid etch to pattern a deposited aluminum film are inappropriate for this material. Several alternative fabrication processes have been reported, including two- and three-layer lift-off techniques,135142170 alkaline etch using a single layer resist,170, and ionbeam milling.142. Most recently, the use of standard processing has been proposed in conjunction with the deposition of a thin Si0 2 passivation layer.171

Table 43. U2B4O7 Hardness. Mohs *6 6-7

Vickers (GPa)

— —

Reference 108 154

4.5. Material properties of diomignite The form of the elasto-piezo-dielectric constants matrices (augmented by the entropytemperature relations) for symmetry class 4mm is shown in Fig. 3. Reported values for the linear dielectric, piezoelectric, and elastic constants and their temperature coefficients for diomignite are listed in Tables 44 and 45, 46, and 47 respectively. The dielectric constant data are separated into different tables for eT and s s . The reported values of the elastic and piezoelectric constants have been obtained from pulse-echo and resonator method measurements, inclusive of SAW and BGW device measurements.

179

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J. A.

Kosinski Table 44. Li 2 B 4 0 7 Relative Dielectric Permittivities at Constant Traction.

E E

T

ll 9.33 9.13 9.32 8.966 9.33 7.81(2) 7.46(2)

....

ET

Frequency

T„(°C)

Reference

10 kHz

109 162 172 123 154 120 120 110

E

33 9.93 10.34 10.1 9.680 10.1 10.25(2) 9.97(2) 10

1 kHz

25 r.t. 25 25

—

—

10 kHz 100 kHz 100 kHz

20 20 25

.... ....

Table 44(a). First Order Temperature Coefficients of Li 2 B 4 0 7 Dielectric Permittivities at Constant Traction (ppm/°C). ET E

ll -4.31

ET

T„(°C)

Reference

25

134

E

33 163

Table 44(b). Second Order Temperature Coefficients of Li 2 B 4 0 7 Dielectric Permittivities at Constant Traction (ppb/°C2).

E E

T

ll 2600

ET

T„(°C)

Reference

25

134

E

33 350

Table 45. Li2B407 Relative Dielectric Permittivities at Constant Strain.

E

ll 8.97±0.05 8.5 8.90 9.04±0.11 8.88 8.91 8.91 8.662

—

43

8.15+0.06 8.2 8.07 8.81+ 0.11 8.46 8.13 8.07 7.893 8.8

180

T„(°C)

Reference

20

104 108 109 173 162 172 154 123 121

— 25 20 r.t. 25

— 25

....

New Piezoelectric

Substrates for SAW Devices

Table 45(a). First Order Temperature Coefficients of Li 2 B 4 0 7 Dielectric Permittivities at Constant Strain (ppm/°C)

£

•fl

33 -33 120 545

-110

-92 97.1

TofC)

Reference

20 20 25

124 173 109

Table 45(b). Second Order Temperature Coefficients of Li 2 B 4 0 7 Dielectric Permittivities at Constant Strain (ppb/°C2).

«?! 2800

T„(°C)

Reference

25

109

E

33

2900

Table 46. Li2B407 Piezoelectric Constants (C/m2).

ei5

e

e33

T„(°C)

Reference

0.36±0.01 0.472 0.278+ 0.005 0.35 0.36 0.39 0.46 0.3918

0.19±0.01 0.290 0.10+0.04 0.38 0.19 0.24 0.23 0.2544

0.89±0.01 0.928 0.77±0.04 0.88 0.87 0.93 0.91 0.8820

20 25 20

—

0.2

0.9

0.492 0.37

— —

—

104 109 173 162 120 172 154 123 174 175 176

31

r.t.

20 25

— 25 25

— —

—

Table 46(a). First Order Temperature Coefficients of Li 2 B 4 0 7 Piezoelectric Constants (ppm/°C). e

15

-1300 -1320 -349 -1050

e31

e

T„(°C)

Reference

-1300

-1000

—

—

-2300 -573

385

20 25 25 25

124 177 173 109

33

-600

1047

1048

J. A.

Kosinski

Table 46(b). Second Order Temperature Coefficients of Li2B407 Piezoelectric Constants (ppb/°C2). «33

T„(°C)

Reference

—

—

-6910

-6500

25 25

177 109

e3i

ei5 5163 -900

Table 47. Li 2 B 4 0 7 Elastic Constants (GPa). C cE3 3

«Fi

•£

«£

126.7+0.1 135 127.1+0.11 135.2 135.27+0.12 126.8 134.2 127.6

0.5+0.2 3.57 6±2 0.8 0.109+0.06 1.0

30+3 33.5 29.4±1.5 31.9 31.8610.10 23.9

8.9

32

128.4 135.823

4.6 -0.285

29.7 31.982

53.910.3 56.8 53.8+8.3 54.9 54.8+0.10 56.2 57.4 54.7 55.5 54.2 54.152

——

— —

— —

— —

c

44 55.010.2 58.5 53.810.4. 55.9 57.3910.08 58.1 47.3 57.5 57.4 57.8 57.072 56.0 57.3

4s 46.010.2 46.7 57.410.5 47.3 47.38+0.06 45.7

T„(°C)

Ref.

20 25 20 r.t. 20 25

104 109 173 162 120 112 121 172 122 154 123 175 176

— 48.2

25 r.t.

47.5 47.680

25

— —

-— —

—

Table 47(a). First Order Temperature Coefficients of Li 2 B 4 0 7 Elastic Constants (ppm/°C).

£

°Fi

-83901100 14000 -67310 1600 3370 20000+10000

-6515 -125 -70.26 -51 -81.1 -80+20

£

cCE 13

E C C33

-485160 350

....

—

—

390 465 5501100

-21 364 400160

10812 -23 -14.53 -22 -18.1 1316

354

4s -22015 -480 -418.6 -200 -272 -480140

ToCC)

Reference

25 20 25 20 25 20

112 124 177 173 109 120

Table 47(b). Second Order Temperature Coefficients of Li2B407 Elastic Constants (ppb/°C2).

«fl

1E2

E C c

-193.1 -440

114939 -17400

—

13

-2300

E C C33 -1800

£

-398.1 500

182

4s 504.4 -450

T„(°C)

Reference

25 25

177 109

New Piezoelectric

Substrates for SAW Devices

1049

The room temperature values of the material constants of diomignite are known with good accuracy and precision.178 The most reliable determination employed an improved resonator method with a total of 67 samples covering seven different orientations.123 All three BAW modes of each sample were measured using both thickness- and lateral-field excitation, typically on the first through ninth harmonics, for a total of 1000 data points used in deriving the elastic and piezoelectric constants.179 The crystals used in the measurements were of exceptional perfection.137 Independent measurements of BGW and SAW devices have confirmed the superior accuracy of this room temperature data set.176'180181 Limited data have been published on the BAW wave velocities of diomignite; these are listed in Table 48.

Table 48. Li2B407 BAW Wave Velocities (m/s). Orientation X-cut X-cut X-cut Y-cut Y-cut Y-cut Z-cut Z-cut (YX1)28.2°

(YX1)45°

(YX1)56°40'

(YXw)45°

(YXwl)45°,45°

(YXwl)45°,56.1°

Polarization long fast shear slow shear long fast shear slow shear long shear long fast shear slow shear long fast shear slow shear long fast shear slow shear long fast shear slow shear long fast shear slow shear long fast shear slow shear

Ref 124

Ref. 121 7415 4896 4410

4407 51xx 4850

Ref. 112 7224 4720 4337 7224 4720 4337 5297 4889

Ref. 178 7458 4922

— 7458 4922

— 5176 4844 7534 4524 4066 7306 4642 3436

— ——

3400±100 6675 5114 4697

6888 4924 7138 5072 3240 6868 4994 3198

1050

J. A.

Kosinski

The temperature coefficients of the diomignite material constants are known with lesser accuracy.140177 While there is a rough agreement on the first order temperature coefficients, there is disagreement concerning even the sign of some of the second order temperature coefficients. In practice, calculations of temperature behavior have proven to be only approximate, and device developments have required significant experimental refinement to accurately identify favorable temperature compensated orientations.108'182'124'183

4.6. Diomignite device properties Diomignite displays good device characteristics in terms of large piezoelectric coupling and zero temperature coefficient of frequency orientations for both BAW and SAW. In both cases, there is an important dependence upon the electrode metallization arising from the extremely high piezoelectric coupling. The calculated zero temperature coefficient BAW orientations are summarized in Table 49. Measured properties for these BAW devices are listed in Table 50. The measured data are in reasonable agreement with respect to the predicted first order temperature behavior, but are in poor agreement with respect to the predicted second order temperature behavior. The measured properties of the TA-cut are particularly interesting.183 The c-mode features nearly zero first and second order temperature coefficients of frequency, and a third order temperature coefficient only half that of quartz. The b-mode features a Qxf product larger than that of AT-cut quartz.

Table 49. Li2B,t07 Calculated Zero Temperature Coefficient BAW Orientations. Mode

Overtone

T(D_o

_U

long long long long long slow slow slow slow slow slow

fund 3rd fund -ira

fund fund

shear nra shear shear fund shear fund shear i nrtl shear fund

'fr (YX1)±38°49' (YX1)±71°52' (YX1)32° (YX1)68°

'fr " ' f r

k (%)

Ref.

.... — — —

124 124 109 109 184 124 124 185 109 109 184

-U

(YXwl)40°,33° (YXl)+48°48' (YX1)±68°17' (YX1)49°14' (YX1)53° (YX1)68°

19.7

25.9

— — (YXwl)19°,56°

26.6

New Piezoelectric

Substrates for SAW Devices

Table 50. Measured Properties of Significant Li 2 B 4 0 7 BAW Orientations. Orientation (YX1)56°40'

Polarization slow shear

(YX1)49°14'

slow shear

(YX1)30°

long

Properties T&) = -300 ppb/°C

2

T( r 2 ) =-280ppb/°C 2

T £ ) =0.7 ppm/°C

Reference 124 185 109

TJ?)=190ppb/°C2 (YXI)30° (YX1)51°

long (fund) slow shear

T^=2.1ppm/°C T ^ = -17ppm/°C

146 109

T< 2) = 320 ppb/°C2 (YX1)51°

slow shear

T ^ = 0 ppm/°C

186

T^ 2 ) =-260ppb/°C 2 (YX1)54°

slow shear

T ^ = 14 ppm/°C

109

T^ 2) = -220 ppb/°C2 (YX1)54° (YX1)56°40' (YX1)68° (YXI)68° (YXwl)40°,33°

slow shear (fund) slow shear (fund) long (3rd OT) slow shear (3rd OT) long

T^ 1 ) =-16.4ppm/°C T^ 2 ) =-300ppb/°C2 T^=0.1ppm/°C T( r 1) =-9.1ppm/°C T ^ = 14 ppm/°C

146 124 146 146 184

T ^ = -220 ppb/°C2 (YXwl)19°,56°

slow shear

T ^ = 2 ppm/°C T (2) =

185

_277 ppb/°C2

184

1051

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J. A. Kosinski

Temperature compensated orientations have been calculated for SAW, leaky SAW, and longitudinal leaky SAW in diomignite; these are listed in Table 51. Due to the inaccuracies in the temperature coefficients of the material properties used in the calculations, the temperature compensated orientations observed experimentally are slightly different from those as calculated. Significant experimental results are listed in Table 52. As noted, the observed temperature coefficient of delay depends strongly upon the thickness of the transducer metallization; all results must be read carefully to determine the range of metallization over which the data are valid. Recently, NSPUDT properties have been identified for the (0°,18°,90°) and (0o,51o,90°) orientations.187 Partial NSPUDT behavior also has been demonstrated for the temperature compensated orientation (0°,78o,90°).187

Table 51. Li2B407 Calculated Zero Temperature Coefficient SAW Orientations. Orientation X-Z (90°,90°,90°) X-Z (90°,90°,90°) X-Z (90°,90°,90°) X-Z (90°,90°,90°) 28 X-Z (90+28°,90°,90°) 17 X-Z (90°+17°,90°,90°) 18 X-Z (90o+18°,90°,90o) (90°,90°+8°,90°) (90°,90°,90°+8°) 45° rotated X-Z 45" rotated X-Z X-Z' 12" rotated prop (0°,73°,75°)

k-1 (%) 0.8±0.1 0.97±0.08 1.1

TCD=10ppm/°C

Velocity (m/s) 3510130 3500±50 3500 3562 3436

1.0

Ref. 188 104 108 189 108

SAW

zero TCD

3465

1.0

108

SAW

zero TCD independent of metallization zero TCD zero TCD metallized zero TCD

1.0

182

1.2 1.0

182 182 190 180 190 191

Mode SAW SAW SAW SAW SAW

Properties parabolic TCD TCD = -llppm/°C TCD = -9 ppm/°C

SAW SAW SAW SAW SAW LSAW

—

— metallized zero TCD zero TCD short and open

3433 3401

—

0.92 1.7

o.oi7 mix (0°,75°,75°) (0°,75°,75°) (0°,75°,42°) (0°,75°,75°) (45°,90°,70°)

LSAW LSAW LSAW LSAW LSAW

(45°,90°,70°) (45°,46o,90°)

LSAW longitudinal LSAW longitudinal LSAW longitudinal LSAW

(0°,45°,90°) (0°,47.3°,90°)

zero TCD zero TCD zero TCD zero TCD zero TCD 0.67 dB/X zero TCD TCD = 10 ppm/°C 0.0001 dB/a. 0.0003 dBIX

4220 4225

1.3 1.8

—

—

4235 3780

1.8 3.6

109 192 192 136 193

3680 6980

1.6

192 194

7074

1.34

195

TCD = -3 ppm/C 0.0005 dB/X

6789.5

1.2

196

186

New Piezoelectric

Substrates for SAW Devices

1053

Table 52. Measured Properties of Significant Li 2 B 4 0 7 Surface Wave Orientations. Orientation X-Z (90o,90°,90°)

Mode SAW

X-Z (90°,90°,90°) X-Z (90°,90°,90°)

SAW SAW

X-Z (90°,90°,90°)

SAW

X-Z (90°,90°,90°) 28° X-Z (90°+28°,90°,90°) 25" X-Z (90°£25°, 90°±10°, 90°+8°) (0°,78°,90°) (0°,90°J8°) (45°,90°,90°) 45° rotated X-Z 45° rotated X-Z (90°+45°,90°,90°) (90°,90°±15°,90°) (0°,75°,75°) (0°,75°,75°) (45°,90°,70°) (0°,47.3°,90°)

SAW SAW

Properties T„=19°C TCD(2) = 310ppb/°C2 TDC = 4 ppm/°C Oppm/C TCD(2) = 230 ppb/°C2 parabolic TCD T„ = 55°C TCD = 6.2 ppm/°C T„ = 20°C TCD(2) = 270 ppb/°C2 TCD < ±5 ppm/°C

SAW SAW SAW SAW SAW SAW SAW SAW LSAW LSAW LSAW longitudinal LSAW

Velocity (m/s) 3510+6

k2 (%) 1.2

Ref. 188

3515 3515

1.06 1%

104 104

3512

0.7%

108

3503 3470

— 0.8

189 108

1

197

zero TCD zero TCD zero TCD 3436 3465

—

TCD(2) = 270 ppb/°C2 TCD<±5ppm/°C TCD < +5 ppm/°C TCD = -1.5ppm/°C TCD = 10 ppm/°C

4120 4224 3670 6676

— TCD=10ppm/°C

1 1.0 1 1 1.6 1.7

— 2.8

109 109 109 180 198 199 199 109 192 192 196

Measured values of acoustic attenuation for diomignite are listed in Table 53. The reported values of the Qxf product are listed in Table 54. The observed device Q of diomignite is close to the maximum possible Q for the X-polarized shear mode in quartz.

Table 53. Li2B407 BAW Acoustic Attenuation. Direction X Z

Polarization long long

Attenuation 15.2 dB/cm@300 MHz 13.2 dB/cm@300 MHz

Reference 121 121

Table 54. Qxf Product for Li2B407. Mode BAW BAW BAW SAW

Orientation (YX1)56°40' (YX1)49°14' (YX1)40°,33° 45° rotated X-Z

Polarization slow shear slow shear fast shear SAW

Frequency fr fr fr fr

Qxf (X 10") 0.172 0.136 2.04 0.465

Reference 124 185 183 190

1054

J. A. Kosinski

References 1. O. Baumgartner, et al., Zeit. Krist, 168 (1984) 83-91. 2. E. C. Shafer and R. Roy, J. Am. Ceram; Soc, 39 (1956) 330. 3. J. Detaint, et al., "Bulk wave propagation and energy trapping in the new thermally compensated materials with trigonal symmetry," Proc. 1994 IEEE Int'l Freq. Control Symp. (1994) 58-71. 4. J. F. Nye, Physical Properties of Crystals: Their Representation by Tensors and Matrices, Clarendon Press, Oxford, 1957. 5. W. G. Cady, Piezoelectricity, Dover, 1946. 6. A. Goiffon, et al., J. Solid State Chem., 61 (1986) 384. 7. A. Goiffon, et al., Rev. de Chimie Minerale, 20 (1983) 338-350. 8. S. Hirano and P. C. Kim, "Physical properties of hydrothermally grown gallium orthophosphate single crystals," J. Mat. Sci., 25 (1990) 4772-4775. 9. D. Cachau-Herreillat, et al., Eur. J. Sol. State Inorg. Chem, 29 (1992) 1295-1307. 10. B. Capelle, et al., "Study of gallium phosphate and langasite crystals and resonators by x-ray topography," Proc. 1994 IEEE Int'l Freq. Control Symp. (1994) 48-57. U . S . Hirano, et al., J. .Crys. Growth, 79 (1986) 215. 12. K. Kosten and H. Arnold, Zeit. Krist., 152 (1980) 119. 13. D. Palmier, "Optimisation de la cristallogenese et de la caracterisation des proprietes piezoelectriques du phosphate de gallium (GaP04), generalisation des relations "structuresproprietes" pour les materiaux de type quartz," These, Univeriste Montpellier.il, November 1996. 14. P. W. Krempl, et al., "GaP0 4 , a critical review of material data," Proc. 9th Eur. Freq. and Time Forum (1995) 66-70. 15. D. Palmier, et al., "New results on the thermal sensitivity of bulk and surface modes of gallium orthophosphate GaP0 4 ," Proc. 1995 IEEE Ultrason. Symp. (1995) 605-510. 16. P. Krempl, et al., "Present state of GaP0 4 research," Proc. 5th Eur. Freq. and Time Forum (1991) 143-147. 17. S. Hirano and P. C. Kim, J. Mat. Sci. 26 (1991) 2805-2808. 18. A. Perloff, "Temperature inversions of anhydrous gallium orthophosphate," J. Am. Ceram. Soc. 39(1986)83. 19. E. Philippot, et al., "New approach of crystal growth and characterization of a quartz and berlinite isomorph: GaP0 4 ," Proc. 1992 IEEE Freq. Control Symp. (1992) 744-752.

188

New Piezoelectric Substrates for SAW Devices 1055 20. E. Philippot, et al., "A quartz-like material: gallium phosphate GaP0 4 , crystal growth and characterization," J. Cryst. Growth 130 (1993) 195-208. 21. B. Capelle, et al., "X-ray topography study of gallium phosphate crystals and resonators," Proc. 7th Eur. Freq. and Time Forum (1993) 659-666. 22. C. Laidler, et al., "Crystal growth and characterization of gallium orthophosphate single crystals," Proc. 8th Piezoelectric Conference Piezo '94 (1994) 259-265. 23. A. Zarka, et al., "Studies of GaP04 Crystals and Resonators," Proc. 1996 IEEE Int'l Freq. Control Symp. (1996)66-71. 24. S. Hirano, et al., "Dielectric properties of hydrothermally grown gallium orthophosphate single crystals," J. Mat. Sci. 25 (1990) 2800-2804. 25. S. Hirano and P. C. Kim, Bull. Chem. Soc. Jap. 62 (1989) 275. 26. A. S. Shiganov, et al., "The solubility of gallium orthophosphate GaP0 4 under hydrothermal conditions," Cryst. Rep. 39 (1994) 648-650. 27. B. Capelle, et al., "X-ray topography study of gallium phosphate crystals and resonators," Proc. 1993 IEEE Int'l Freq. Control Symp. (1993) 813-820. 28. I. A. Danikov, et al., "Electromechanical properties of gallium phosphate between -196 and +723°C," Sov. Phys. Cryst. 36 (1991) 277-279. 29. G. Engel, et al., "Technical aspects of GaP0 4 , " Proc. 3rd Eur. Freq. and Time Forum (1989) 5056. 30. W. Wallnofer, et al., "Determination of the elastic and photoelastic constants of quartz-type GaP0 4 by brilloin scattering," Phys. Rev. B 49 (1994) 10075-10080. 31. F. Huard, These Universite de Montpellier (1985). 32. C. Reiter, et al., "Temperature dependence and compensation of GaP0 4 thickness resonators," Proc. 12th Eur. Freq. and Time Forum (1998) 447-450. 33. W. Wallnofer, et al., "Temperature dependence of elastic constants of GaP0 4 and its influence on BAW and SAW devices," Proc. 7th Eur. Freq. and Time Forum (1993) 653-657. 34. J. Detaint, et al., "Optimization of the design of the resonators using the new materials: application to gallium phosphate and langasite," Proc. 1997 IEEE Int'l Freq. Control Symp. (1997) 566-578. 35. E. H. Briot, et al., "A comprehensive mapping of surface acoustic wave properties on gallium orthophosphate (GaP0 4 )," Proc. Joint Meeting Eur. Freq. and Time Forum and IEEE Int'l Freq. Control Symp. (1999) 811-815. 36. E. Philippot, et al., J. Sol. State Chem. 110 (1994) 356. 37. "Standards on Piezoelectric Crystals, 1949," Proc. IRE 37 (1949) 1378-1395. 38. "IEEE Standard on Piezoelectricity", IEEE/ANSI Std. 176-1987 (1988).

189

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New Piezoelectric Substrates for SA W Devices 1065 199. H. Suzuki, et al., "Surface acoustic wave device," U.S. Patent 4,672,255, issued June 9, 1987. Al. A. A. Kaminskii, etal., "Crystal structure and stimulated emission of La3Ga5 5Nbo.50i4-Nd3+," Inorg. Mat. 20 (1984) 1793-1796. A2. P. A. Senjushenkov, et al., "Temperature characteristics of langanite bulk wave vibrations," in Proc. 1996 IEEE Int'l Freq. Control Symp. (1996) 137-140. Bl. S. K. Frederick, et al., "Swept frequency acoustic time domain measurements," Proc. Joint Meeting 1999 IEEE Int'l Freq. Control Symp. and 13th Eur. Freq. and Time Forum (1999).

Appendix A - Langanite Material Properties

Table Al. La3Ga5.5Nbo.5O14 Critical Temperatures. Melting Point (°C) 1430±20 1470 1450 1510

Transition Point (°C)

— none

— —

Reference 50 A2 67 66

Table A2. La3Ga5.5Nbo.5O14 Lattice Constants. a (A)

c(A)

T„(°C)

8.218±0.005 8.235+0.005

5.122±0.005 5.129+0.002

20

—

Reference 41 Al

Table A3. La3Ga5.5Nbo.5O14 Mass Density. Mass Density (kg/m') 5934 5934.7+13 5903

Method x-ray x-ray measured

Reference 41 this work 50

ToCQ 20 20

—

Table A4. LasGas sNb0 5Oi4 Thermal Expansion. aj 1 / (ppm/°C)

(X33 (ppm/°C)

4.32

3.09

T„(°C)

Reference

20

95

Table A5. La3Ga55Nbo5Oi4 Relative Dielectric Permittivities at Constant Traction. £8

T

11 20.3 20.2

C33 79.3 79.4

Frequency

T„(°C)

Reference

1 kHz 1 kHz

20 20

94 95

199

1066

J. A.

Kosinski Table A5(a). First Order Temperature Coefficients of I^GassNbosOu Dielectric Permittivities at Constant Traction (ppm/°C).

E

E

33 -1500

ll

30

T0(°C)

Reference

20

95

Table A5(b). Second Order Temperature Coefficients of La3Ga5.5Nbo.5O14 Dielectric Permittivities at Constant Traction (ppb/°C2). s

E

ll 180

33 2360

T„(°C)

Reference

20

95

Table A6. La3Ga5.5Nbo.5O14 Relative Dielectric Permittivities at Constant Strain.

*Sn

E33

19.53 19.57

79.3 79.4

T„(°C)

Reference

20 20

this work using 94 this work using 95

Table A7. La3Ga5.5Nbo.5O14 Piezoelectric Constants (C/m2). e14 0.12 0.05

eil -0.467 -0.44

T0(°C)

Reference

20 20

94 95

Table A7(a). First Order Temperature Coefficients of La3Ga5.5Nbo.5O14 Piezoelectric Constants (ppm/°C). eil 750

en 39500

T„(°C)

Reference

20

95

Table A7(b). Second Order Temperature Coefficients of La3Ga5.5Nbo.5O14 Piezoelectric Constants (ppb/°C2). ei4 -83900

eil -4500

ToCC)

Reference

20

95

Table A8. La3Ga5.5Nbo.5Ou Elastic Constants (GPa).


<& 108.6 109.3

°?3

ClE4

102.3 98.2

10.99 13.5

c

C33

259.0 260.5

200

44 48.57 50.4

& 40.0 40.7

T„(°C)

Reference

20 20

94 95

New Piezoelectric

Substrates for SA W Devices

1067

Table A8(a). First Order Temperature Coefficients of La3Ga5.5Nbo.5O14 Elastic Constants (ppm/°C).

'11 -77

«£

4


E C C33

C44

-112

-84

-502

-108

-50

4

-29

To(0C)

Reference

20

95

Table A8(b). Second Order Temperature Coefficients of La3Ga5.5Nbo.5Ou Elastic Constants (ppb/°C2).

<1E1

41

«f2

cc

E

6.4

CE

«£

13 348

C33 -22

-850

c

44 -942

4

885

T„(°C)

Reference

20

95

Appendix B - Langatate Material Properties Table Bl. La3Ga5.5Tao.5O14 Critical Temperatures. Transition Point (°C)

— — .... —

Melting Point (°C) 1470+20 -1500 1470 1510

Reference 50 96 67 66

Table B2. La3Ga5.5Tao.5O14 Lattice Constants. Reference c(A) T„(°C) 20 41 8.225+0.005 5.123±0.005 8.151 5.105 50 —

a (A)

Table B3. La3Ga55Tao5Oi4 Mass Density. Mass Density (kg/mJ) 6164 6150 6167.0±13.5

Method x-ray x-ray x-ray

Reference 41 Bl this work

T„(°C) 20 20 20

Table B4. La3Ga5.5Tao.5O14 Relative Dielectric Permittivities at Constant Traction. E E

T

ll 18.5

ET

E33 60.9

Frequency

T„(°C)

Reference

1 kHz

20

96

Table B5. La3Ga5.5Tao.5O14 Relative Dielectric Permittivities at Constant Strain.

«?1 17.53

E33 60.9

T„(°C)

Reference

20

this work using 96

201

1068

J. A.

Kosinski Table B6. La3Ga5.5Tao 5 0u Piezoelectric Constants (C/m2). e14 0.07

eil -0.54

T„(°C)

Reference

20

96

Table B7. La3Ga5 sTaosOu Elastic Constants (GPa).

«f.

<&

«£

<£

189.4 191.2

108.4 111.22

132.0 108.5

13.7 13.5

c

33 262.9 267.6

c

44 51.25 51.52

4e 40.52 39.99

T„(°C)

Reference

20 20

96 Bl

International Journal of High Speed Electronics and Systems, Vol. 10, No. 4 (2000) 1069-1109 © World Scientific Publishing Company

PSEUDO AND HIGH VELOCITY PSEUDO SAWs MAURICIO PEREIRA DA CUNHA Dept. of Electronic Systems Eng., Escola Politecnica da Universidade de Sao Paulo, Av. Prof. Luciano Gualberto, Trav.3, n3. 158, 05508-900, Sao Paulo, Brazil

This article discusses the characteristics of pseudo surface waves (PSAWs) and high velocity pseudo surface waves (HVPSAWs). The fundamental properties of these waves, the matrix method formulation, the different solution types due to crystal symmetry, early experiments on HVPSAWs, and practical applications of pseudo surface acoustic waves serve as an introduction. The solutions to the pseudo modes are discussed by analyzing the boundary condition function for several orientations. The relation between the radiating partial modes and the sagittal plane bulk slowness reveals new characteristics of the different symmetry types of HVPSAW, and helps classify and understand the pseudo modes. The acoustoelectric Poynting vector is used along different crystal symmetry orientations to reveal and discuss the pseudo SAW characteristics: penetration depth, declination of the power vector, and an estimation of power flow angle. Experimental data and numerical solutions of HVPSAW and PSAW along selected planes and orientations are discussed. This article concludes with a brief analysis of layered structures on different symmetry type substrates and a discussion of the layered pseudo surface wave properties.

1. Introduction This article discusses pseudo surface acoustic waves or pseudo SAWs, also known as "leaky SAWs" or "leaky waves." Particular attention is given to the high velocity pseudo surface acoustic wave, or HVPSAW. The work is divided into four major sections. Section 1 is an introduction, addressing the basic concepts of the pseudo SAWs, the different solution types, early experiments on HVPSAW, and current pseudo SAW applications. Section 2 discusses pseudo SAW fundamentals. The basic equations used in the matrix method formalism are revisited and the solution to the propagation problem focuses on pseudo SAWs. The classification of the orientation symmetries is highlighted as fundamental in understanding pseudo SAW behavior and properties. Section 3 discusses the pseudo SAW solutions. Starting with an analysis of the boundary condition function for different boundary conditions, the section proceeds with a discussion of the Poynting vector. Important pseudo SAW characteristics for practical applications are described, and the concepts of penetration depth, declination of the Poynting vector, and estimated power flow angle are reviewed. The relationship between the radiating partial modes, RPM, responsible for the power radiation into the substrate, and the bulk slowness is addressed. Pseudo SAW solutions in the plane and along specific orientations of practical interest conclude this section. Solutions in layered structures, their importance and characteristics for the pseudo SAWs, are the focus of Section 4. The relevance of the layer thickness and material in practical device applications is discussed, and properties of the pseudo SAW solutions in layered structures are analyzed. Section 5 concludes this work.

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1.1. Basic Concepts The HVPSAW and the pseudo SAW, PSAW, first discussed by Engan et al and by Lim and Farnell, share the same fundamental propagation characteristics.1'2 Both the HVPSAW and the PSAW are pseudo surface waves in the sense diat they are a form of coupled modes that can exist on anisotropic free surfaces and consist of a linear combination of phase matched decaying and radiating partial modes that together satisfy the mechanically free surface boundary conditions. The decaying partial modes, DPM, are the components that decay with depth, whereas the radiating partial modes, RPM, are the components that radiate power into the substrate, resulting in an attenuation of the field amplitudes as the wave propagates. This attenuation is only due to radiation of power and is not dissipation due to viscosity, an effect that is neglected in this article. When the contribution of the radiating term(s) is(are) sufficiently small, the pseudo modes are detectable in standard surface acoustic wave devices. The early experiments and numerical treatments mention that the type of PSAW analyzed has a higher phase velocity than the transverse bulk wave in the direction of propagation.1'2 To account for this property, the authors of references 1 and 2 suggested and verified that a combination of decaying partial modes and a radiating partial mode is required to satisfy thefreesurface boundary condition. 1.2. Different Solution Types Although the pseudo SAWs are sometimes called leaky SAWs in the literature, the present work does not use the term "leaky" which is also used to refer to liquid-solid boundary conditions where energy leaks from the solid into the liquid. The present work deals with radiation of power into the semi-infinite solid. To avoid confusion with the leakage of energy into liquids, a topic not treated in this work, the term pseudo SAW, introduced in Ref. 2, is used for both the PSAW and the HVPSAW. The PSAW is a coupled mode that contains only one radiating partial mode, all others being decaying partial modes. The RPM radiates inside the solid to the slow shear bulk mode in the sagittal plane. Regarding the particle displacement fields, the mechanically free PSAW usually has the shear horizontal component of the particle displacement field as the dominant component. Another characteristic of the mechanically free PSAW is that the value of the phase velocity is usually close to the fast shear bulk wave velocity in the direction of propagation. The HVPSAW has one or two radiating partial modes, depending on the symmetry of the orientation of propagation discussed in Section 2. If only one RPM is present the HVPSAW radiates inside the solid to the fast shear bulk mode in the sagittal plane. If two RPMs are present the HVPSAW radiates inside the solid to the slow quasishear bulk mode and to the fast quasi-shear bulk mode in the sagittal plane. The particle displacement field for the mechanically free HVPSAW usually has the longitudinal component as the dominant term. The designation high velocity PSAW was originally chosen because the value of the phase velocity for this wave lies close to the longitudinal bulk wave velocity in the direction of propagation.3'4 The term SAW is used here exclusively for the true surface acoustic wave solution, which is strictly guided by the surface.

204

Pseudo and High Velocity Pseudo SAWs

1071

1.3. Early Experiments on HVPSA W Like the PSAW, the experimental evidence for the HVPSAW goes back over two decades. Some of the early experiments that detected the HVPSAW classified this wave as: "longitudinal bulk wave," "surface skimming bulk wave," "shallow bulk acoustic wave," or "quasi-bulk acoustic surface wave"; mostly due to the proximity of the phase velocity to the planar longitudinal bulk wave velocity in the direction of propagation.5,6'7,8,9,1° The name "surface skimming bulk wave" has also been used for both PSAW and HVPSAW in early publications.611 Since a bulk acoustic wave, BAW, in a piezoelectric material does not satisfy the mechanically free boundary conditions, the mode experimentally identified could not be a BAW . The existence of an independent high-velocity pseudo SAW mode was identified by researchers from Brillouin scattering experiments on cubic materials.12 Jhunjhunwala also discussed the pseudo SAWs, grouping them as first or second order pseudo SAWs, according to the number of radiating partial modes.13 As mentioned in 1.2, the HVPSAW might have one or two radiating partial modes, depending on the symmetry of the orientation of propagation. Therefore a classification according to the number of radiating partial modes is not appropriate. Reference 12 estimates the HVPSAW to have high loss for the gallium arsenide, GaAs, orientations discussed in that paper. This is not the case for other materials and orientations as discussed in this paper and in recent ~ „ W i ; ™ * ; ~ , . „ 4,14,15,16,17,18,19,20

publications. 1.4. Applications of Pseudo SA Ws One major reason for the recent interest in pseudo SAWs lies in their higher phase velocities. The PSAW has phase velocities around 40% higher than the SAW, and the HVPSAW, 100% higher than the SAW. For the most common SAW materials and orientations used, the values of SAW phase velocity is around 3.0 to 3.5 Km/s, which limits the frequency of SAW devices to a few GHz. For a minimum dimension in the photolithographic process, which defines the wavelength, ZMN, a higher value of phase velocity, vpMAX, extends the operating frequency limit of the SAW devices, JMAX, hi accordance to vpMAX = XMIN ./MAX -3'21 Harmonic operation of SAW devices has been used in the past to achieve higher frequency of operation. This approach presents difficulties in designing high performance devices, such as: less control in the desired device response, higher losses, higher spurious levels, and greater sensitivity to surface defects. These problems are avoided with the proper orientation selection of a PSAW or HVPSAW device. Several recent electronic systems require higher operating frequencies, high performance, and low loss devices. Examples of such . systems are: wireless communication equipment, including cellular phones, mobile phones, local area networks, cordless phones, pagers, and global positioning systems (GPS); security systems; and controlling and remote sensing systems.22 The PSAW and the shear horizontal (SH) modes, with vp about 40% higher than the SAW, have been used in recent high frequency applications, as a means of extending the operating frequency of SAW devices.23'24 The HVPSAW devices and applications appeared recently in GPS and

205

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M. P. da Cunha

communication systems, further extending the operating frequency of SAW devices.14'15'17 An interesting characteristic of the low propagation loss pseudo modes for high frequency devices is that the pseudo SAW orientations have a higher fraction of the power carried deeper inside the material, as compared to the SAW mode. This characteristic, named penetration depth in Ref. 3, is addressed in this work. A larger penetration depth means that the wave power is less confined to the surface. This is suitable for high frequency devices, since the pseudo waves, PSAW and HVPSAW, are less sensitive to surface defects than the SAWs. The smaller sensitivity to surface defects translates into lower losses and higher performance devices, provided the selected pseudo SAW orientation has low propagation loss and that damping is negligible. Still considering high frequency low loss devices, one should mention the potential pseudo SAW applications of metallic layered structure;25'26 the ZnO/diamond/Si, where values of vp above 14 Km/s are found for the HVPSAW;27'28 and the ZnO/SiC, vp HVPSAW^I 1 Km/s.29 The film thickness is a critical parameter to achieve low propagation loss for the pseudo SAWs. Materials like diamond and SiC have high stiffness constants, uius higher phase velocity modes, when compared to commonly used SAW orientations on LiNb03, LiTa03, and quartz. Finally, the pseudo SAWs have application for liquid sensors, due to their particle displacement polarizations. The SAW wave has a large vertical component of particle displacement field, and is generally strongly attenuated by a fluid on the device's surface. The PSAW orientations which are interesting for liquid sensor applications have a large shear horizontal particle displacement, which is not severely attenuated in liquid environments.30 The HVPSAW, with high longitudinal particle displacement, parallel to the surface, is potentially interesting for liquid sensor applications, with low attenuation expected. 2. Fundamentals of Pseudo SAWS This section discusses the fundamental properties of the pseudo SAW modes. Subsection 2.1 introduces the orientation classification that is important in the wave classifications and in finding the acoustic solutions. Sub-section 2.2 reviews the basic equations used in the matrix method. The types of HVPSAW solutions based on the orientation classification are discussed in Sub-section 2.3. The boundary function characteristics, the complex slowness, and the solution approach are discussed in Subsections 2.4, 2.5, and 2.6, respectively. 2.1. Symmetry Classification: Uncoupling ofModes Figure 1 shows the type of structure considered in the present work and the coordinate system adopted. The substrate is considered semi infinite, and may have a mechanically free surface, electrically shorted or open, or yet multiple layers on top of its surface. Although only one layer is shown in Fig. 1, the matrix method analysis adopted in this work can handle multiple layers.31 In order to refer to orientations, the commonly used Euler angles are adopted.32 The material constants used are taken from multiple

206

Pseudo and High Velocity Pseudo SAWs

z

hX

|

y /

1073

propagation ^

layer

substrate

Fig. 1. Structure considered and coordinate system adopted.

An arbitrary orientation of propagation, x axis in Fig. 1, can be classified according to the symmetry type specified by the crystal and the selected orientation.38 This also determines the number of roots, or partial modes, also called partial waves, involved in a surface acoustic wave problem. The classification is fundamental to properly sort out the several types of acoustic waves, thus allowing a better comprehension of the PS AW and the HVPSAW solutions. Table 1 presents the substrate orientation classification, including the associated wave types and the conditions on the elastic stiffness constants (C;J) and the piezoelectric constants (e^) with respect to a propagation direction.3 Recalling that the layer material considered in Fig. 1 may also assume any of the symmetry types enumerated, in the case of a layered problem the type of the solution will be that of the lowest symmetry possible for the problem. Symmetry type 1, or Sym 1, describes the general acoustic wave case of lowest crystal symmetry. In this situation the material is piezoelectric, and the wave particle motion has components in all three directions u x , u y , and u z . A SAW propagating in this orientation is named Generalized SAW (GSAW), and this orientation is called a GSAW direction. Symmetry type 2, or Sym 2, represents non-piezoelectric materials, where the GSAW problem must be solved. Symmetry type 3, or Sym 3, portrays the situation where the sagittal components decouple from the shear horizontal component. The stiffened sagittal SAW, also referred to as Rayleigh wave, is excited for a mechanically free surface. A pure mechanical shear horizontal wave also exists in a layered situation. An example of this propagation symmetry is the well-known YZ-LiNb03 orientation. Symmetry type 4, or Sym 4, refers to another uncoupled situation, in which the stiffened shear horizontal wave and a pure mechanical sagittal SAW wave, also referred to as Rayleigh wave, are present. This is the case for the 36.3°-Y rotated AT quartz (Euler angles: [0° -54.7° 90°]);12'13 the ST quartz (Euler angles: [0° 132.75° 90°]);13 the Bleustein-Gulyaev wave (CdS Euler angles: [0° 90° 0°]).39 Finally, symmetry type 5 refers to the pure mechanical acoustic waves in non-piezoelectric substrates, where the sagittal-plane displacement components uncouple from the transverse component. Before relating the PSAW and the HVPSAW to the symmetry classification of Table 1, a review of the matrix method equations is carried out next.

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M. P. da Cunha Table 1. Substrate crystal symmetry types and wave types relative to Fig. 1: c- are the elastic stiffness constants and e- are the piezoelectric constants for a propagation direction.

SYMMETRY

WAVE TYPES

Type 1 (piezoelectric substrate) Type 2 (non-piezoel. substrate)

lowest symmetry; general case.

Type 3 (piezoelectric substrate)

stiffened sagittal Rayleigh wave and pure mechanical shear horizontal wave stiffened shear horizontal wave and pure mechanical Rayleigh wave

Type 4 (piezoelectric substrate)

CONDITIONS

general elastic anisotropy (but non-piezoel.)

eij

=o

c

14 = c 16 = c 34 = c 36 = = c 45 = c 56 = ° e 14 = e 16 = e 34 = e 36 = ° c

14 = c 16 = c 34 = c 36 = = c 45 = c 56 = ° e i i = e , 3 = e15 = e31 = = e 33 = e 35 = °

Type 5 (non-piezoel. substrate)

pure mechanical acoustic waves

eij c

14

= c

=o

= c

16 34 = c 3 6 = c 45 = c 56 = °

2.2. Basic Equations In this sub-section the major statements in the matrix method formalism applied to SAW propagation problems are summarized.40,41 A comprehensive treatment by Eric L. Adler appears as a companion article. One of the key advantages of the method is that it reduces the acoustoelectric equations to a set of first-order vector-matrix ordinary differential equations of at most size 8, 6 for non-piezoelectrics, in the variables that must be continuous across interfaces. In the layered case, one such matrix exists for each layer, and die interfacial boundary conditions are automatically satisfied by a matrix multiplication that preserves the dimensionality of the problem. The coordinate system is shown in Fig. 1. Although the method can handle any number of layers, for simplicity only one layer is shown in this figure. The z axis is normal to the layer interfaces. The assumed solution form, for sinusoidal travelling waves along x at a radian frequency co radians per second, is f(z) exp U(
kx x)J = f(z) exp [ja>(t-—)]

(1)

with vp and kx=o^vr representing the phase velocity and propagation constant along x respectively. The vector of normal stresses, Tz, and the particle velocity vector, v, are respectively represented (components in their r.m.s. form) by

208

Pseudo and High Velocity Pseudo SAWs

1075

(2)

T2 =

(3) These are the six mechanical variables, which must be continuous across interfaces. For piezoelectrics the time derivative of the electric potential (jcofy and the normal electric displacement, Dz, are chosen as the two electric variables which must be continuous. These 6 or 8 variables are a sufficient independent set and all other variables can be expressed in terms of them, using the set of dynamic and constitutive equations of a material. For problems unbounded normal to the z plane with the propagation direction along x in the xy plane, the problem is two-dimensional, there are no variations in the y direction, hence d/dy=0 and d/dx=-ja/vp. The vector r is defined as the six-component vector for nonpiezoelectric materials (4) For piezoelectric materials the corresponding eight-component vector is defined

\Tz ] Dz V

T„

(5)

L^vJ

_yco

with T„=[ Tz Dzf and rv=[v jaxfif, and the superscript "t" indicating transpose; r„ and rv are 4x1 vectors. The differential equation at a> radians/second describing transverse, or z, variations in the sinusoidal steady-state for the material is — = y© AX (6) dz where the system matrix A is a function of the phase velocity vp and of material constants rotated to the coordinate system of Fig. 1. For multilayer problems, (6) applies in each material and r must be continuous at each interface. The matrix A is T'3 X

G-


- r " xr3')

A=

(7) XT

209

31

1076

M. P. da Cunha

where the submatrices X and .Tin the case of non-piezoelectric materials are 3x3 containing, respectively, compliance and stiffness constants referred to the coordinate system of Fig. 1; and the submatrix G0=pl3x3, with p the mass density of the material and I3x3 the 3x3 identity matrix. For piezoelectric materials the submatrices X and /"are 4x4 and contain compliance, stiffness, piezoelectric, and permittivity constants; G0 is also 4x4 having zeros in the fourth row and column. The submatrices X, r, and G0 are given by c

m

c

c

21Vc

c

212k

c

2l3k

e

c

31t

c

3l2k

c

3/3t

e

e

e

e

lVc

c

V2k

l2k

V3k

l3k

e

kll k21

(8)

k3l

~elk

X=(T33 rl

(9)

p 0 0 0 0 p 0 0 G = 0 0 p 0 0 0 0 0

(10)

The solution to (6) is 1(z + dh) = exp(j(x>Adh ) X(z) = U exp(\dh )V'x(z)

= ^1X(z)

(11)

with &r=exp(jwAdh) the material state transition matrix that maps x across a distance dh in the z direction within the same material, U the 8x8 eigenvector matrix of ihejaA material matrix, the columns of {/are the eigenvectors ofjcaA, A is the diagonal eigenvalue matrix of jcaA, and r =U'T is the normal mode or uncoupled state vector. For SAW problems, and considering that the half-space occupies z<0, all fields must vanish as z goes to negative infinity. For the substrate, since only four of the eigenvalues decay with depth, it follows that at a semi-infinite substrate surface the state vector is T(0) = USp Tv(Q)

(12)

where USp is the 8x4 submatrix corresponding to decaying modes of the substrate eigenvector matrix, Us; and TJJ(0) is the corresponding 4x1 half of the normal state vector, with the "u" index indicating upper half.

210

Pseudo and High Velocity Pseudo SAWs

1077

2.3. The Boundary Condition Function (BCF) This sub-section refers to symmetry Type 1 problems, since this is the most general type. The discussion of the other symmetry types is deferred to Sub-section 2.6, when the pseudo SAW modes are classified. The boundary conditions require that at mechanically free surfaces Tz vanishes, and for piezoelectric materials with short-circuited surface <j)=0 at the top surface "0 0 0 = « U

V°)

= &TOTAL USp 1v(0)

(13a)

v 0 with &roTAL obtained by multiplying the layer transmission matrices. A matrix QT is defined from {0TOTAL UsP) by interchanging the fourth and eighth rows in (13a). Defining QTu by selecting the first four rows of QT 0 0 0 0

= QTuTu(0)

(13b)

TOP

This equation has non-trivial solutions if and only if det[QTu]

=0

(14)

which is the boundary conditions (BC) determinantal equation for the multilayer on halfspace problem. For the mechanically free half-space SAW problem, the boundary determinant equation is directly obtained from (12) using the boundary conditions as in (13), and defining the matrix QTS from USp in (12) by interchanging the fourth and eighth rows of USp. Defining QTSu as the first four rows of QTS, det[(grs„]=0 is obtained. For electrically open-circuited surfaces the electric fields must satisfy Laplace's equation in the free space. The solution for D^free space) is given by s0coftvv and by subtracting Dz(free space) from the fourth element in rmP=[0 0 0DZ vjcofi]' for the free surface, an equation equivalent to (13) is written. The resultant numerical procedure consists in searching for vp such that the boundary conditions, expressed by (14), are satisfied. The four mechanically free boundary conditions statements are taken from (13). For a GSAW on symmetry Type 1 the four partial modes that decay with depth, are selected out of the eight partial modes in the substrate. The resulting boundary condition statement is expressed by (14), and is referred to diroughout this work as the Boundary Condition Function (BCF). There are other ways of expressing the boundary condition statement (14), and the effective permittivity is one of these alternative ways.31

211

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M. P. da Cunha

All the other variables are expressed in terms of the six, non-piezoelectrics, equation (4), or eight, piezoelectrics, equation (5), variables chosen. For the fields in the direction of propagation, x, the vector TP is defined and its relation with x given by

T13 X

r"AT J ' - r-//

•pT

(15)

For the fields in they direction, normal to the sagittal plane, the vector xh is defined and its relation with T given by xy

T yy

Y23 X

T23xr31-r»

ht1

(16)

T

y*

[Dy\ where matrices p and h t , defined in (15) and (16) respectively, are 4x8 for piezoelectric materials and are functions of material constants and phase velocity only. For nonpiezoelectric materials, T P =T X =[ T^ Txy Txz ]' and T i ,=T y =[T yx T yy T yz ] t , and p and h, are 3x6.

2.4. Complex Slowness One might ask what happens to the boundary condition function, BCF, in the vicinity of the expected PSAW and HVPSAW velocities if only decaying partial modes are considered. For the PSAW case, selecting only the decaying modes, a minimum in the BCF is often observed near the expected PSAW velocity.2 Sometimes a minimum is also observed near the expected HVPSAW velocity. In Fig. 2 the BCF for the real slowness is expressed as the effective permittivity, and one can notice the quartz AT GSAW solution, and two minima near die PSAW and HVPSAW velocities, respectively. These minima, however, cannot be decreased to zero by adjusting the values of a real vp parameter. If one of the four partial modes in the substrate is a radiating partial mode, i.e., an eigenvalue of jcoA that grows with depth, a complex slowness must be used. The complex slowness is written as y= l/vp-j a/co, in exp(-ja>pc) = exp{-x (a+jkx)}, with kx=cofvv, and a, the attenuation constant. By considering a complex slowness, the BCF determinant can be decreased to zero, in the sense that further iterations result in smaller values of the determinant, until the computer accuracy is reached. The linear system of equations, (6), now has complex coefficients since the slowness is complex. The matrix A becomes complex when l/vp is replace by y. The fields of the resulting solution attenuate in the x direction as this mode propagates, and the solution is a PSAW in a symmetry Type 1 situation. If two radiating partial modes are used in the substrate for a symmetry Type 1 problem, the solution is a HVPSAW.

212

Pseudo and High Velocity Pseudo SAWs

^

8.

10 5

,*

/ '

* t>

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0

£ o

3.5

4

4.5 5 Phase velocity [Km/s]

5.5

I 10 I 5 .1 0

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4

4.5 5 Phase velocity [Km/s]

5.5

Fig. 2. Plot of the normalized effective permittivity, Stff/Eo, as a function of real slowness along quartz AT (Euler angles:[0° -54.7° 0°]).

Finding the solutions of either a PSAW or a HVPSAW requires finding the zero of the complex BCF of two real variables, vp, and a, the attenuation constant. Once the PSAW or the HVPSAW solution is found, the respective complex slowness, y, is known. If the solution for the pseudo problem has a high attenuation then the minima in the BCF observed in Fig. 2 might not be detected in the vicinity of the pseudo SAW phase velocity solutions. PSAW and HVPSAW practical orientations must have relatively low attenuation so that it makes sense to talk about propagation of such waves. Typical plots of the BCF for complex slowness are discussed in Section 3. 2.5. How the Problem is Solved As is clear from (13) and (14) the BCF has an implicit dependence on the real or complex slowness, therefore solving SAW and pseudo SAW problems requires numerical minimization. For a pseudo SAW problem, an initial guess is assigned for the complex slowness, y= l/vp -j a/co, (6) is solved and the BCF determinant, (14), is calculated and the equality to zero checked. The process is repeated for successive values of vp and a with the aid of a multivariable minimization program until (14) is satisfied to within some predetermined accuracy.

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2.6. Types ofHVPSA WSolutions Based on Symmetry Classification This section classifies the pseudo SAWs in terms of the orientation symmetries given in Sub-section 2.1, and in light of the surface wave problem solution outlined in Sub-section 2.2. Characteristics of the pseudo SAW solutions in terms of the particle displacement polarization, the phase velocities, and the type of BAW that radiates power into the substrate are given in Section 3. For the lowest symmetry Type 1, a surface wave solution is built from a linear combination of four partial modes in the semi-infinite substrate to satisfy (14). For the GSAW four decaying partial modes are selected. If one of the four partial modes chosen is a radiating partial mode, the solution is a PSAW. If two radiating partial modes are selected, the solution is an HVPSAW. Due to the radiating partial modes, the fields attenuate as they propagate, but if the contribution of the radiating terms are sufficiently small, these pseudo modes are observed in standard surface acoustic wave devices. For symmetry Type 2, (14) is 3x3, the material is non-piezoelectric, and a surface wave solution is built from a linear combination of three partial modes in the semi-infinite substrate. For the GSAW, three decaying partial modes are selected. For the PSAW and HVPSAW, one and two of the partial modes, respectively, are selected to be radiating partial modes. For symmetry Type 3, the sagittal components decouple from the shear horizontal ones, and (14) is 3x3 for the piezoelectric active solutions. A stiffened surface wave solution is built from a linear combination of three partial modes in the semiinfinite substrate. For the sagittal SAW, Rayleigh wave, three decaying partial modes are selected. If one of the three partial modes is chosen to be a radiating partial mode, the solution is a HVPSAW. This is not a PSAW for reasons that are outlined in Sub-section 1.2 and exemplified in Section 3. In a symmetry Type 4 orientation, the material is piezoelectric, the stiffened shear horizontal solution decouples from the pure mechanical sagittal solution, and (14) is 2x2 for both solutions. Two decaying partial modes are used to build up the stiffened shear horizontal wave and the other two are used for the pure mechanical Rayleigh wave solution. For symmetry Type 5, the material is non-piezoelectric, and the sagittal components decouple from the shear horizontal one. A surface wave solution is built from a linear combination of two partial modes in the semi-infinite substrate. For the sagittal SAW wave (Rayleigh wave) the two decaying partial modes are selected. If one of the two partial modes is a radiating partial mode the mode is a HVPSAW.4212

3. Characteristics of PSAW and HVPSAW Solutions This section discusses the properties and characteristics of the pseudo SAW solution. Sub-section 3.1 shows typical boundary condition functions and considers their behavior for different materials, boundary conditions, and symmetry types. The Poynting vector declination, the power flow angle calculation, and the penetration depth for the pseudo SAWs are described in Sub-section 3.2. The relationship between the radiating partial modes and bulk slowness is addressed in Sub-section 3.3. Examples of PSAW and HVPSAW solutions are given in 3.4.

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Pseudo and High Velocity Pseudo SAWs

1081

3.1. The Boundary Condition Function (BCF) Recalling that the pseudo SAW BCFs depend on vp and a, the BCFs are plotted as a function of those two real variables. Figure 3 a shows the HVPSAW BCF magnitude for the mechanically free shorted surface of symmetry Type 1 quartz ST-25° (Euler angles: [0° 132.75° 25°]), and Fig. 3b shows the two dimensional view of the same plot with respect to the phase velocity axis. As can be noted from these two plots, the BCF has several local minima, which work as traps for a multi-variable optimization routine. Although the multiple local minima behavior can also be observed in the single variable SAW problem, it is more pronounced in the pseudo SAW multi-variable case. Figure 3b also clearly identifies the actual HVPSAW solution at vp=6.5262 Km/s. Note that the BCF decays gradually around several local minima, whereas around the HVPSAW solution the BCF has a comparatively steeper behavior. This behavior usually poses an additional degree of difficulty in finding and tracking the HVPSAW solutions when varying the direction of propagation. An appropriate starting point is very important in finding the HVPSAW solution. Figure 4 compares the BCF between the free, Fig. 4a, and the shorted, Fig. 4b, surface for the symmetry Type 1 mechanically free Li 2 B 4 0 7 (Euler angles: [0° 75° 75°]). Normally the solution for the shorted surface is easier to find than the solution for the electrically free surface, since under shorted boundary condition the energy of the wave is usually trapped closer to the surface, and the pseudo SAWs behave more like a surface mode. The same behavior is observed in pseudo SAW layered problems, Section 4, or when grating structures are used on top of a semi-infinite substrate.25'17'18 The BCF in the electrically free surface, Fig. 4b, has a larger overall gradient with vp and a when compared to the electrically shorted surface, Fig. 4a. In such cases, the use of bounded minimization routines in the complex slowness plane and the careful selection of the initial guess are very important in finding the solution. Still referring to the symmetry Type 1 mechanically free Li 2 B 4 0 7 (Euler angles: [0° 75° 75°]), Fig. 5 shows the BCFs of the electrically shorted HVPSAW (Fig. 5a) and PSAW (Fig. 5b) around me respective solution regions. One notes that the HVPSAW BCF has a steeper behavior around the solution when compared to the PSAW BCF, a typical behavior for symmetries Type 1, also detailed for quartz ST-25° (Euler angles: [0° 132.75° 25°]) in Ref. 3. Note, however, that along symmetries Type 3, where only one radiating partial mode leads to a HVPSAW solution (Sub-section 2.6), the HVPSAW BCF behaves like a PSAW BCF on a symmetry Type 1 orientation. Figure 6 is an example of a HVPSAW BCF along a symmetry Type 3, the mechanically free electrically shorted Li2B407 (Euler angles: [0° 45° 90°]). Normally when there is only one radiating partial mode instead of two, the energy of the wave is trapped closer to the surface, and the pseudo SAW behaves more like a surface mode. When there are two radiating partial modes, the BCF is usually steeper close to the solution when compared to the one radiating partial mode problem. The steeper behavior of the HVPSAW BCF on symmetry Type 1 with respect to the PSAW BCF along symmetry Type 1 and the HVPSAW BCF on symmetry Type 3, usually implies that it is more difficult to find the solution to the HVPSAW BCF on symmetry Type 1 when compared to the other problems.

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216

Pseudo and High Velocity Pseudo

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Attenuation [Np/Km]

Phase Velocity [Km/s] (b)

Fig. 4. Plot of the HVPSAW BCF magnitude as a function of vp and a along Li2B407 (Euler angl [0° 75° 75°]) for the mechanically free: (a) shorted surface; (b) free surface.

217

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Attenuation [Np/Km]

Phase Velocity [Km/s]

S-60 HD.01

Attenuation [Np/Km]

Phase Velocity [Km/s] (b)

Fig. 5. Plot of the BCF magnitude as a function of vp and a along Li2B407 (Euler angles: [0° 75° 75°]) for the mechanically free shorted surface: (a) HVPSAW; (b) PSAW.

218

Pseudo and High Velocity Pseudo SAWs

Attenuation [Np/Km]

0

6.5

1085

Phase Velocity [Km/s]

Fig. 6. Plot of the HVPSAW BCF magnitude as a function of vp and a along the symmetry Type 3 Li 2 B 4 0 7 (Euler angles:[0° 45° 90°]) for the mechanically free shorted surface.

3.2. The Poynting Vector and the Power Flow Angle This subsection analyzes the characteristics of the acoustoelectric Poynting vector for the pseudo SAWs. The specific topics discussed in this subsection are: (i.) the Poynting vector penetration depth; (ii.) the declination of the Poynting vector, its tilt down into the solid, as a function of depth; (iii.) the power flow angle, PFA. The Poynting vector for piezoelectrics is defined by43 P = Re {- v *. T + <)> 0 (o D )'}

(17)

or equivalently P = Re { - v * . r - 0 H > / Z ) } = Re {-T'V . Tn } (18) with " ' " the transpose conjugate operator; rv and x„ are defined in (5). For the BAW problem, P points in the direction of power flow and is invariant from point to point in the infinite solid. For the SAW problem, there is no power flow normal to the mechanically free surface, since all partial modes are decaying partial modes, allfieldsvanish as z goes to minus infinity, and the wave is strictly guided by the surface.44 The magnitude and the direction of the power are obtained by integrating P.dA, over the area of a unit width strip and infinite depth. The eigenvalues of (j^A) in (11), which correspond to the partial modes of the pseudo SAW problem, can be written as (tfi+jka), in e?q){z(ai+jkzl)}, with k^co/Vzi. For the decaying partial modes, DPM, o, are positive in accordance to the coordinate system adopted in Fig. 1. For the radiating partial modes, RPMs, a ; are negative. Note that the power

219

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M. P. da Cunha

crossing any area in the solid is taken to be I P.dA over the area in question. As pointed out in Ref. 2 for the case of the PSAW, carrying out this integration over any closed surface within the solid, the resultant value must be zero to be consistent with the interpretation of the pseudo surface waves and the non-dissipative assumption regarding the medium. For the pseudo SAW orientations of practical interest, meaning those orientations where the pseudo modes can be generated and detected by standard surface acoustic wave devices, one observes that: i.) The amplitudes of the decaying partial modes are much larger than those of the radiating partial modes; ii.) The magnitude of decay rates of the decaying partial modes are larger than the magnitude of growth rate of the radiating partial modes. When i.) and ii.) apply, the pseudo mode behaves like a surface mode: P is large near the surface; P is almost parallel to the surface close to the surface; and the attenuation a is low. A high propagation loss pseudo SAW solution transfers power to one or two of the radiating partial modes within a short distance. 3.2.1. Penetration depth Figure 7 shows the plots of the Poynting vector [TW/m2] in the direction of propagation as a function of the normalized depth for the PSAW, Figs. 7a, and for the HVPSAW, Figs. 7b, along the mechanically free shorted surface symmetry Type 1 quartz AT (Euler angles: [0° -54.7° 0°]). Figure 8 is equivalent to Fig. 7 for an aluminum layered surface (h/^FSAw=l%)- From these figures, which represent practical PSAW and HVPSAW orientations, one may notice that P is large near the surface, decaying after a few wavelengths inside the semi-infinite substrate, where the only remaining partial modes are the radiating partial modes, only visible in these figures for the HVPSAW. One notices from the comparison between Figs. 7a and 7b that the PSAW power decays to relatively negligible values after approximately 20 wavelengths, whereas a relatively significant fraction of power is observed in Fig. 7b for the HVPSAW after 20 wavelengths. This behavior is expected along this symmetry Type 1 substrate, since the PSAW has only one radiating partial mode, whereas the HVPSAW has two radiating partial modes. Characterizing the distribution of power inside the semi-infinite substrate by penetration depth, as done in Ref. 3, a comparison between Figs. 7a and 8a shows that the aluminum layer reduces the penetration depth from around 20 wavelengths to 10 wavelengths for the PSAW. The HVPSAW, Figs. 7b and 8b, is less affected by the same aluminum layer thickness, reflecting the effect of the two radiating partial modes that typically distributes a relatively larger fraction of power inside the material in this symmetry Type 1 orientation. Figure 9 shows the plot of the Poynting vector for the HVPSAW along the mechanically free shorted surface symmetry Type 3 Li2B407 (Euler angles: [45° 45° 90°]). Since only one radiating partial mode exists, one sees that for this symmetry type 3 HVPSAW the power decays to a relatively negligible value after about 1.5 wavelengths, denoting the strong surface guiding behavior this mode has for this orientation.

220

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222

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The pseudo SAWs have a larger penetration depth when compared to the SAW, since about 90% of SAW wave power is contained in one wavelength. The pseudo SAW modes are thus less sensitive to surface defects than SAWs at high frequencies, a practical advantage of the pseudo SAW modes. At lower frequencies the finite thickness of the substrates may need to be considered in device design in light of the higher penetration depth of the pseudo SAW modes. 3.2.2. Declination of the Poynting vector As observed from Figs. 7 to 9, below some depth, the radiating terms are the only ones left in the solution and the direction of P is mainly dictated by the associated radiating partial modes. Figure 10 shows the declination of the Poynting vector, its tilt down into the solid, for both PSAW, Fig. 10a, and HVPSAW, Fig. 10b, as a function of normalized depth for the mechanically free shorted surface symmetry Type 1 quartz AT (Euler angles: [0°-54.7° 0°]). Figure 11 plots the declination of the Poynting vector for the HVPSAW on the mechanically free shorted surface symmetry Type 3 Li2B407 (Euler angles: [45° 45° 90°]). In Figs. 10 and 11, the declination of the Poynting vector is zero close to the surface, as expected for a PSAW or a HVPSAW orientation of practical interest. For both the PSAW represented in Fig. 10a and the HVPSAW represented in Fig. 11, there is only

223

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224

Pseudo and High Velocity Pseudo SAWs

-

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Fig. 11. Plots of the HVPSAW declination of the Poynting vector as a function of the normalized depth for the mechanically free shorted surface symmetry Type 3 symmetry Type 3 Li2B407 (Euler angles: [45° 45° 90°]).

one radiating partial mode. In these cases the declination of the Poynting vector is unambiguously dictated by the radiating partial mode after a depth has been reached where the decaying partial modes contributions have become negligible. As can be observed from Fig. 10b, the declination of the Poynting vector for die symmetry Type 1 HVPSAW has the influence of both radiating partial modes, after the DPMs have become negligible. A similar behavior is reported for quartz ST-25° (Euler angles: [0° 132.75° 25°]).4 3.2.3. Powerflowangle Provided the pseudo SAW mode behaves like a surface mode in the sense that that P is large near the surface, which means that the power is concentrated near the surface, an approximate power calculation is performed. As suggested in Ref. 2 for the PSAW and in Ref. 4 for the HVPSAW, the magnitude and the direction of the power flow can be evaluated approximately by performing the integration of P over a strip of unit width and some finite depth. In the case of HVPSAW along symmetry Type 3 and die PSAW a suitable depth is around a couple of wavelengths. For die HVPSAW along symmetry Type 1, the integration usually needs to be done for a larger depth, due to die existence of two radiating partial modes, and the fact that die decaying fields are still significant at a few wavelengths away from the surface. The choice of depth to use in integration varies from orientation to orientation according to die P behavior with depth, and therefore it is helpful to plot die deptii behavior of P before choosing an integration depth.

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Using the procedure mentioned in the previous paragraph, the power components px and py necessary to calculate the azimuth angle between P and the direction of propagation can be approximately evaluated, and the power flow angle, PEA, estimated as PFA=tgA(py /px). Good agreement between the PEA predictions and experimental results are reported in reference 4 when a depth of around 14 wavelengths was considered along the quartz ST-25° orientation. 3.3. The Relationship between Radiating Partial Modes and Bulk Slowness This subsection discusses the relationship between the PSAW and HVPSAW radiating partial modes and the bulk waves that are radiated inside the semi-infinite substrate, according to the type of bulk wave and the direction of propagation. The partial modes that enter the pseudo SAW solution have been genericalfy written as (<Ji+jk^, in exp{z(<Ji+jk„)}, vnthkzi=a>/vz,. In accordance to the coordinate system adopted in Fig. 1, Oj are necessarily negative and kd positive for the RPMs, since these partial modes radiate power towards the interior of the semi-infinite substrate. Recalling from Subsection 2.2 that the wave vector in the direction of propagation is given by k^a/Vp, Fig. 12 defines the tilted radiating partial mode wave vector, kBi, and its angle to the surface, #,, that is calculated using3

e,=#-x' kO

(19) V xJ The wave velocity associated with the radiating partial mode, v B ;, is calculated from Fig. 12 by 1 1 1 — = — + ~T (2°) v v

<

l

l

or equivalently Vm=vpcos0i

(21)

Equations (19) to (21) allow the calculation of the orientation inside the semi-infinite substrate where a specific radiating partial mode radiates, and the phase velocity of the associated bulk mode. Table 2 gives, in the third column, the radiating partial modes for both PSAW and HVPSAW along some illustrative free surface orientations, namely: the symmetry Type 3 Li 2 B 4 0 7 (Euler angles: [0° 45° 90°]); the symmetry Type 1 Li 2 B 4 0 7 (Euler angles: [0° 75° 75°]); symmetry Type 1 quartz AT (Euler angles: [0° -54.7° 0°]); and symmetry Type 1 quartz ST-X (Euler angles: [0° 132.75° 0°]). The fourth column gives the 0, and vBi calculated from (19) and (21), and associated with the respective radiating partial mode from the third column. The fifth column shows the Euler angles associated to the direction of propagation $ in sagittal plane, and the three BAW phase velocities calculated at 6t.

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Pseudo and High Velocity Pseudo SAWs

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K<=co/vp

Fig. 12. Wave vectors representation in the sagittal plane.

Although both HVPSAW along symmetry Type 3 and PSAW have only one radiating partial mode, a very distinct characteristic of the HVPSAW with respect to the PSAW may be observed from Table 2 regarding the type of bulk mode that radiates inside the solid. Selecting for instance the HVPSAW along symmetry Type 3 Li2B4C>7 (Euler angles: [0° 45° 90°]), note from Table 2, column 4, that the vBi associated with the radiating partial mode that radiate power inside the semi-infinite substrate is 5.014 Km/s. From Table 2, column 5, one sees that this radiating partial mode radiates power to the fast quasi-shear bulk mode along the corresponding orientation in the solid. Figure 13a illustrates the radiation of this radiating partial mode to the fast quasi-shear bulk. The direction of the Poynting vector associated with the radiating partial mode and normal to the fast quasi-shear bulk slowness curve, can also be inferred from Fig. 13a to be around 45°, as calculated in Ref. 4. Observing now PSAW along symmetry Type 1 Li2B407 (Euler angles: [0° 75° 75°]), the respective vBi from Table 2, column 4, is 3.535 Km/s. From Table 2, column 5, one sees that this radiating partial mode radiates power to the slow quasi-shear bulk mode along the corresponding orientation in the solid. The radiation of the PSAW radiating partial mode to the slow quasi-shear bulk mode is depicted in Fig. 13b. Therefore, while the radiating partial mode in a HVPSAW along symmetry Type 3 radiates power to the fast quasi-shear bulk mode, the PSAW radiating partial mode radiates power to the slow quasi-shear bulk mode. Figure 13b also depicts the HVPSAW along symmetry Type 1 Li2B407 (Euler angles: [0° 75° 75°]) and the two associated radiating partial modes presented in Table 2. Note that one of the HVPSAW radiating partial modes radiates power to the slow quasishear bulk mode, whereas the other radiates power to the fast quasi-shear bulk mode, as predicted in Table 2.

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Table 2. PS AW and symmetry Types 1 and 3 HVPSAW radiating partial modes (third column); calculation of 6! and v a using (19) and (21), respectively (fourth column); sagittal plane slowness: verification of (21) and relation to the bulk modes radiation shown double underlined. Material and orientation (Euler angles) symmetry TYPE

Wave Partial modes that grow Type with depth (free surface) [s/Km]

Li2B407 [0° 45° 90°] TYPE 3

HVPSAW

Li2B407 [0° 75° 75°] TYPEl

PSAW

-7.41e-7+j 0.14067

^•n(eql9) ### vBi [Km/s] (eq.21)

Euler angles [°] @ 0t Bulk wave velocities [Km/s] @ 9t

44.86

[90 -90 -0.1416] [4.376, 5.014, 7.440]

### 5.014 -3.29e-5+j0.1556

33.37

###

[86.0 284.5-41.13] [3.535. 4.743, 7.452]

3.535 -2.15e-5+j0.1779

48.08

### HVPSAW

[86.0 284.5 -26.42] [4.183. 4.596, 7.544]

4.183 -1.74e-4+j0.1439

42.01

###

[86.0 284.5 -32.49] [3.901,4^2,7.5341

4.652 quartz AT-X [0° -54.7° 0°] TYPEl

-2.88e-6+j0.117

30.77

###

PSAW

[0 215.3 30.77] [4.381.4.830, 5.349]

4.381 -1.08e-5+j0.137

38.10

### HVPSAW

[0 215.3 38.10] [4.521. 4.730, 5.374]

4.521 -1.72e-5+j0.115

33.45

###

[0 215.3 33.45] [4.470, 4.794, 5.327]

4.794 quartz ST-X [0° 132.75° 0°] TYPEl

-1.53e-4+j0.115

30.3

###

PSAW

[0 215.3 30.3] [4.385. 4.761, 5.447]

4.385 -1.72e-5+j0.115

36.68

### HVPSAW

[0 215.3 36.68] [4.607. 4.624, 5.442]

4.607 -6.6e-6+j0.1284

36.41

### 4.623

228

[0 215.3 36.41] [4.608, 4.623, 5.439]

Pseudo and High Velocity Pseudo SAWs

1095

90 86 DEC

180

270

(a)

180

270

(b) Fig. 13. Slowness curves [s/Km]. a.) Sagittal plane of Li2B407 Euler angles [0° 75° 75°]: Li 2 B 4 0 7 Euler angles [86.0° 284.5° -74.5°], represented at zero degrees, b.) Sagittal plane of Li 2 B 4 0 7 Euler angles [0°45°90°]: Li 2 B 4 0 7 Euler angles [90°-90°-45°], represented at zero degrees. The angles exhibited indicate the orientations of the radiating terms inside the material, calculated from the PSAW and HVPSAW growing partial modes (Table 2).

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3.4. PSAW and HVPSAW Solutions The first experimental evidences for the HVPSAW were published during the late seventies.5,6' 7'8 The experimental HVPSAW data available on rotated Y-cuts of quartz has also been reported in subsequent works.9'419,20 Figure 14 shows phase velocity and attenuation for both pseudo modes on the entire quartz ST plane, Euler angles [0° 132.75° v|/]. The phase velocities for the GSAW, PSAW and HVPSAW are shown in Fig. 14a, together with those of the three BAWs. Figure 14b gives the propagation attenuation of the HVPSAW and PSAW modes for the ST plane. Note that the attenuation of both PSAW and HVPSAW vary in the plane, reaching low enough values for practical devices around several orientation intervals. Figures 15 and 16 illustrate the GSAW, PSAW and HVPSAW solutions for the X axis boule cut Euler angles [<> | 8 vj/]= [0° 6 0°] on a promising new SAW material, langatate (La3Ga5 sTao.sOu), that has a temperature behavior comparable to quartz, but with higher piezoelectric coupling.36,37,45 Note from Fig. 15 that both GSAW and PSAW solutions cease to exist on the orientations where these modes approach the slow or the fast BAW velocity value, respectively, whereas the HVPSAW exist for the entire plane, although with relatively high losses, Fig. 16a. The relative fractional phase velocity, K2=2|Avp|/Vp = 2|vshort-Vfree|/vfree, for the pseudo PSAWs is shown in Fig. 16b. The HVPSAW has received considerable attention in the past few years on Li2B407.14,15,10,3 Experimental HVPSAW devices have also been built on LiNb03 and LiTa03, and the mode has also been identified in other materials like GaAs.16,17,1812 Table 3 presents HVPSAW solutions along selected orientations in order to discuss some characteristics of this mode. The first column gives the selected orientations; the respective HVPSAW solution for vp and a are given in the second and third columns for both electrically shorted and free surfaces. The values of the three BAW modes and the value of the SAW solution are included in the first and second column in brackets for reference purposes. Column 4 lists the particle displacement field for both electrically shorted and free surfaces. The orientation symmetry type is also included in this column. The estimated powerflowangles according to the procedure discussed in Subsection 3.2, and the 2|Avp|/vp are displayed in column five. In addition to the HVPSAW characteristics regarding the radiating partial modes and how they radiate inside the semi-infinite substrate, other attributes of the HVPSAW solutions are now discussed. One relevant HVPSAW characteristic is the proximity of the phase velocities to the quasi-longitudinal bulk wave phase velocity, which makes the fabrication of high frequency SAW devices easier. As seen in column 2, the HVPSAW phase velocities reach values 100% higher than those of the SAW. Another property of the HVPSAW is the strong longitudinal particle displacement field obtained for most solutions. From column 4, the magnitude of the longitudinal particle displacement, ux, is usually dominant. An additional characteristic for certain orientations is the fact that for the HVPSAW to behave like a surface wave, it may require a guiding structure, like a shorted surface or a grating, to concentrate the power close to the surface as discussed in Sub-section 3.2.4,16,17,18 Quartz ST-250, LiNb03 (Euler angles: [90° 90° 36°]), and LiTa03 (Euler angles: [90° 90° 31°]), given in Table 3, are such examples. For completeness, Table 4 includes PSAW solutions for selected materials and orientations. Table 4 has the same form as Table 3. An important PSAW characteristic is

230

Pseudo and High Velocity Pseudo SAWs

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(b) Fig. 14. Quartz ST plane Euler angles [0° 132.75° y]: (a) Phase velocity for the GSAW, PSAW and HVPSAW modes, also including the three BAW; (b) attenuation for the PSAW and HVPSAW modes.

231

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5

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140

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40

60

80

100

120

140

160

180

THE [DEGRES]

(b) Fig. 15. X axis boule cut Euler angles [<)i8x))]= [0°8 0°] phase velocities [Ktn/s]: (a) HVPSAW and PSAW, including the longitudinal and fast shear BAW modes; (b) GSAW, including the slow shear BAW.

232

Pseudo and High Velocity Pseudo SAWs

HVPS/ w PSAW

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120

140

160

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Fig. 16 X axis boule cut Euler angles [$ 61|/]= [0°8 0°]: (a) PSAW and HVPSAW attenuation [dB/>.]; (b) PSAW and HVPSAW K2 [%].

233

1099

1100

M. P. da Cunha Table 3.

High velocity pseudo-SAW (HVPSAW) for some selected materials and orientations.

VBULK [Km/s]

V

P short/ open

ill

Material and orientation (Euler angles, [°])

< V SAW >

Li2B407

[Km/s] 6.9879 7.0418 (3.0998)

Fields @ z=0 u

*>Vuz>

short/open (magnitude [Km] ) symmetry type

PFA[°] short/ open 2|Av p |/v p [%]

6.1e-3 5.8e-5

1 0 0.03 1 0 0.01 TYPE 3

0 0 1.53

7.0267 7.0740 (3.2658)

l.le-2 2.9e-4

1 0 0.061 1 0 0.037 TYPE 3

0 0 1.34

6.8641 6.9120 (3.2557)

1.3e-2 6.7e-4

1 0 0.09 1 0 0.07 TYPE 3

0 0 1.39

[0 75 75 ] [3.689 4.936 6.439]

6.2405 6.2611 (3.3090)

0.460 0.041

1 0.686 0.364 1 0.675 0.307 TYPEl

-20.3 -27.1 0.66

GaAs [45 -90 25 ] [2.654 2.990 5.376]

5.3987 5.3986 (2.5339)

1.9e-2 1.6e-3

1 0.04 0.234 1 0.04 0.233 TYPEl

2.8 2.9 0.004

quartz AT-X [0 -54.7 0 ] [3.298 5.100 5.744]

5.7447 5.7454 (3.1510)

1.0e-2 2.5e-3

1 0.12 0.077 1 0.12 0.080 TYPEl

-0.2 -0.1 0.023

quartz ST-X [0 132.75 0 ] [3.298 5.100 5.744]

5.7446 5.7449 (3.1576)

6.0e-3 1.2e-3

1 0.066 0.081 1 0.056 0.084 TYPEl

-0.5 -0.7 0.011

quartz ST-25 [0 132.75 25 ] [3.365 4.032 6.604]

6.5262

1.8e-5

1 0.35 0.090

14.1

[45 45 90] [3.238 5.046 7.238] Li2B407 [0 45 90 ] [3.446 4.644 7.409] Li2B407 [0 47.3 90] [3.479 4.632 7.437] Li2B407

LiNb0 3 [90 90 36 ] [4.0214.029 7.315] LiTa0 3 [90 90 31 ] [3.336 3.365 6.316] LiTa0 3 [90 90 42 ] [3.347 3.359 6.347]

TYPE 1

(3.2475) 6.8085 7.3404 (3.6616)

3.8 6.4e-2

1 0.34 0.48 1 0.08 0.24 TYPEl

-12.7 -0.08 14.5

6.2442 6.3179 (3.1420)

0.56 8.0e-3

1 0.19 0.25 1 0.09 0.13 TYPEl

1.3 3.5 2.3

6.2922 6.3512 (3.1420)

0.59 1.0e-2

1 0.14 0.26 1 0.04 0.16 TYPEl

-0.7 -0.5 1.9

the proximity of the phase velocities to the fast quasi-shear bulk mode phase velocity. The PSAW phase velocities reach values around 40% higher than the SAW values, as seen in column 2. In the PSAW case, column 4 shows that the magnitude of the shear horizontal particle displacement, uy , is usually dominant.

234

Pseudo and High Velocity Pseudo SAWs Table 4.

1101

Pseudo-SAW (PSAW) solution for some selected materials and orientations.

Material and orientation (Euler angles, [°]) VBULK [Km/s]

Li2B407 [0 75 75 ] (3.689 4.936 6.439)

V

P short/ open rvFREEi [Km/s] 4.1958 4.2329 (3.3090)

a short/ open [dB/X.]

Fields @ z=0 ux,uy,uz, short/open (magnitude [Km] ) symmetry type

PFA[°] short/ open 2|Av p |/v p [%]

3.0e-2 1.6e-2

1 0.92 0.46 1 1.05 0.44 TYPEl

25.7 27.3 1.8

[0 -54 0 ] (3.3514.227 5.589)

4.1091 4.2267 (3.1252)

2.7e-4 2.1e-4

1 15.2 1.85 1 26.7 0.47 TYPEl

-0.053 -0.006 5.6

quartz AT-X [0 -54.7 0 ] (3.298 5.100 5.744)

5.0994 5.0996 (3.1510)

1.8e-3 1.3e-3

1 6.70 0.33 1 6.66 0.31 TYPEl

-0.034 -0.035 0.008

quartz ST-X [0 132.75 0 ] (3.298 5.100 5.744)

5.0781 5.0789 (3.1576)

7.9e-2 7.8e-2

1 2.40 0.37 1 2.39 0.36 TYPEl

0.040 0.055 0.033

quartz ST-25 [0 132.75 25] (3.365 4.032 6.604) 64 LiNbOj

4.0166 4.0181 (3.2475)

7.8e-2 8.1e-2

1 2.34 0.60 1 2.32 0.59 TYPEl

-28.8 -28.7 0.074

4.4505 4.6919 (3.6799)

3.7e-3 5.2e-2

1 8.58 3.23 1 3.58 0.60 TYPEl

0.6 2.2 10.3

4.3781 4.7515 (3.6412)

1.4e-2 2.4e-4

1 51.2 20.0 1 23.8 0.79 TYPEl

-0.83 0.02 15.7

[0 90 29.2 ] (3.432 3.678 5.989)

3.5123 3.5444 (3.2056)

7.0e-l 8.2e-l

1 3.42 1.45 1 3.49 1.69 TYPEl

2.54 2.54 1.8

quartz [0 15 0 ] (3.298 5.100 5.744)

3.9547 3.9569 (3.2911)

1.7e-4 1.4e-4

1 0.33 0.93 1 0.34 0.93 TYPEl

-0.053 -0.048 0.11

36 YX-LiTa0 3

[0 -26 0 ] (4.0314.752 6.547) 41 LiNbOj [0 -49 0 ] (4.0314.752 6.547) LiTaOj

4. Layered Solutions This section addresses the importance of layer thickness and materials on pseudo SAW devices. It focuses on a discussion of the layer parameters that affect a pseudo SAW device performance and highlight the properties of layered solutions with examples.

4.1. The Importance of the Layer Thickness and Materials in Practical Devices Any surface acoustic wave device is influenced by a material layer, such as: the metallic film of the transducer, a film deposited in the propagation path, or the device might be a layered structure. The layer thickness and material directly affects the pseudo SAW complex slowness solution, vp and a. The layer thickness also modifies the penetration depth, the power flow angle, the particle field Dolarization, and the values of 2|AvD|/vD. 235

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M. P. da Cunha

For high performance devices, especially if one is considering portable applications where the systems are battery operated, the importance of low loss devices is evident. In the next section some examples are given, showing that a proper choice of the layer material and thickness leads to significantly reduced values of a. A knowledge of the dispersion characteristic is fundamental in high performance device design and in group delay response prediction. A layer usually has a strong effect on the penetration depth. As shown in Figs. 7 and 8, a layer may concentrate the power associated with the propagating wave closer to the surface, and thus cause the pseudo SAWs to behave more like a surface mode. Other practical consequences that result from the knowledge of the layer effect on a certain mode penetration depth are: the required quality of the surface mechanical polishing; and the substrate thickness in order for the substrate to be appropriately considered semiinfinite. In references 25 and 26 the particle displacement fields are tabulated as a function of thickness for the HVPSAW on an aluminum layered symmetry Type 1 LiNb03 (Euler angles: [90° 90° 164°]), and for the PSAW on an aluminum layered symmetry Type 1 LiTa03 (Euler angles: [0° -26° 0°]). Knowing the particle displacement fields is important in calculating practical devices parameters, such as the electrode reflection coefficient, fundamental in SAW device design. Finally, the power flow angle estimation allows proper placement of the transmitting and receiving transducers in practical devices where the PFA^Q. The PFA as a function of thickness has also been addressed in references 25 and 26, using the HVPSAW LiNb03 and the PSAW LiTa03 examples cited in the preceding paragraph. One should also mention the importance of layered structures such as ZnO/diamond/Si and ZnO/SiC in achieving phase velocities as high as 14 Km/s for the HVPSAW in high frequency applications.46'47> 48 4.2. Properties of Solutions in Layered Structures This subsection discusses properties of the layered pseudo SAWs solutions which have an impact on both practical devices design and in the fundamental understanding of the pseudo modes. Figures 17 and 18 show the phase velocity and attenuation as a function of the thickness times frequency, hf, for two aluminum layered orientations: symmetry Type 3 Li2B407 (Euler angles: [0° 47.3° 90°]), Fig. 17; and symmetry Type 1 LiNb03 (Euler angles: [90° 90° 164°]), Fig. 18. The upper part of Fig. 17 shows velocity plots for the HVPSAW, three lossless pure sagittal particle motion Rayleigh modes, and the phase velocity values of the three BAW modes. The HVPSAW propagation attenuation is plotted in the lower part of Fig. 17. Note that since this orientation refers to a symmetry Type 3 there is no PSAW. The upper part of Fig. 18 shows velocity plots for the HVPSAW, the PSAW and a higher order PSAW, five generalized SAW modes and the phase velocity values of the three BAW modes along that orientation. The lower part of Fig. 18 plots the propagation loss for the HVPSAW, the PSAW and a higher order PSAW mode. Note from Fig. 17 that a minimum in the propagation loss occurs close to hf=0.2 Km/s (vp=6.7413 Km/s), h/^=3%, a reduction of more than two orders of magnitude when compared to the mechanically free electrically shorted surface. This is a relevant

236

Pseudo and High Velocity Pseudo SAWs

1103

7.5 quasi-l ingitud nal 7 6.5 6

v

5.5

/ \ V

s

5

fast shear

4.5 4 3.5 . 1

3

0

1

~2

2 3 4 5 6 7 T H I C K N E S S x F REQU ENCY

3

V ¥

8 9 (hfHKm/sl

10

7 8 9 (hf)[Km/s]

10

101

/ '

§10° z

LU 1 UJ

|

10"1

OQ Z

-2

O 10

/

1 in4

1

2 3 4 5 6 THICKNESSx FREQUENCY

Fig. 17. Layered substrate: phase velocity (upper part) and attenuation (lower part) versus (thickness x frequency). Aluminum layered symmetry Type 3 Li 2 B 4 0 7 (Euler angles: [0° 47.3° 90°]. HVPSAW: dash-dot; lossless Rayleigh modes (pure sagittal particle motion): Solid (first and second), and star (third); larger-dots: BAW phase velocities.

237

1104

M. P. da Cunha 7 quasi longitu dinal

6.5 6 1

5.5

8

test c uasi-sl iear

Qj 4.5

> ui

3

4

\ 0

X

0

slaw iuasi-s tear

x

^ ^ ° 9 * +*•*»

1

Q-

5

4 2

3.5 1 3 1.5 2.5

1 1.5 2 2.5 3 3.5 THICKNESS x FREQUENCY

4 4.5 ( h f ) [Km/s]

5

5.5

5

5.5

10

x iO LU

/

I

> 0

o

°o0

_„0

-i 10

§

0

m -o z

Q , Sc 10

10'

pI \

0.5

1 1.5 2 2.5 3 3.5 THICKNESS x FREQUENCY

4 4.5 ( h f ) [Km/s]

Fig. 18. Layered substrate: phase velocity (upper parts) and attenuation (lower parts) versus (thickness x frequency). Aluminum layered symmetry Type 1 LiNbOj (Euler angles: [90° 90° 164°]). HVPSAW: dash-dot; higher order PSAW: circles; PSAW: dashed; first to fourth GSAW: solid; fifth GSAW: star; largerdots: BAW phase velocities.

238

Pseudo and High Velocity Pseudo SAWs

1105

HVPSAW characteristic that can be advantageously used in device design and fabrication. Such behavior has also been observed in PSAW orientations, like quartz ST25° (Euler angles: [0° 132.75° 25°]), 36° YX LiTa0 3 (Euler angles: [0° -54° 0°]), and 64° YX LiNb0 3 (Euler angles: [0° -26° 0°]).4'25' 26 ' 49 ' 50 For 0.2
239

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M. P. da Cunha

Numerical and experimental HVPSAW and PSAW orientations and planes are listed and analyzed. Finally, solutions for selected orientations in layered structures and the relevance of layer materials and thickness are discussed based on experimental and numerical results.

Acknowledgments The author is indebted to many suggestions and proofreading of the manuscript by Eric L. Adler, and to fruitful discussions with Prof. Donald C. Malocha. The support of the Brazilian National Council for Scientific and Technological Development (Conselho Nacional de Desenvolvimento Cientifico e Tecnologico - CNPq); the Sao Paulo Research Foundation (Fundagao de Amparo a Pesquisa do Estado de Sao Paulo - FAPESP); and the Advanced Materials Processing and Analysis Center - AMPAC, University of Central Florida, USA, which enable the realization of different parts of the work reported in this article, are gratefully acknowledged.

References 1. H. Engan, K. A. Ingebrigtsen, and A. Tonning, "Elastic surface wave in a-quartz: observation of leaky surface waves," Appl Phys. Lett., vol. 10, pp. 311-313, June 1967. 2. T. C. Lim and G. W. Farnell, "Character of pseudo surface waves on anisotropic crystals," The Journal of the Acoustic Society of America, April 1969, vol. 45, No. 4, pp. 845-851. 3. M. Pereira da Cunha, "Extended investigation on high velocity pseudo surface waves," IEEE Trans. Ultrason. Ferroelec. Freq. Contr., vol. 45, no. 3, May. 1998, pp. 604-613. 4. M. Pereira da Cunha and Eric L. Adler, "High velocity pseudosurface waves (HVPSAW)," IEEE Trans. Ultras., Ferroel, Freq. Contr., vol. 42, No. 5, Sept. 1995, pp. 840-844. 5. T. I. Browning and M. F. Lewis, "New family of bulk-acoustic-wave devices employing interdigital transducers," Electronics Letters, March 1977, Vol. 13, No. 5, pp. 128-130. 6. M. Lewis, "Surface skimming bulk waves - SSBW," in Proc. IEEE Ultras. Symp., 1977, pp. 744-752. 7. K. H. Yen, K. F. Lau, and R. S. Kagiwada, "Recent advances in shallow bulk wave devices," in Proc. IEEE Ultras. Symp., 1979, pp. 776-785. 8. A. Ballato and T. J. Lukaszek, "Shallow bulk acoustic wave progress and prospects," IEEE Trans, on Micr. Theory and Tech.., vol. 27, No. 12, Dec. 1979, pp. 1004-1012. 9. C. A. Flory and R. L. Baer, "Surface transverse wave analysis and coupling to interdigital transducers," in Proc. IEEE Ultras. Symp., 1987, pp. 313-318. 10. N. F. Naumenko, "Quasihorizontal polarized quasibulk acoustic surface waves piezoelectric crystals," Sov. Phys. Crystallogr., Vol. 37, No. 2, March-April 1992, pp. 220-223.

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Pseudo and High Velocity Pseudo SAWs

1107

11. K. Y. Hashimoto, M. Yamaguchi, and H. Kogo, "Experimental verification of SSBW and leaky SAW propagating on rotated Y-cuts of LiNb0 3 and LiTa03," in Proc. IEEE Ultras. Symp., 1983, pp. 345-349. 12. G. Carlotti, D. Fioretto, L. Giovannini, F. Nizzoli, G. Socino, and L. Verdini, "Brillouin scattering by pseudosurface acoustic modes on (l l l) GaAs," Journal of Physics: Condensed Matter, 1992, Vol. 4, pp. 257-262. 13. A. Jhunjhunwala, "Spectrum of Acoustic Waves Excited in Single and Multiple Layered Crystalline Media," Ph.D. Thesis, University of Maine, USA, 1977. 14. M. Adachi, T. Shiosaki, K. Ohtsuka, and A. Kawabata, "Leaky SAW propagation properties on Li 2 B 4 0 7 substrates," in Proc. IEEE Intern. Freq. Contr. Symp., 1994, pp. 296-300. 15. T. Sato and H. Abe, "SAW device applications of longitudinal leaky surface waves on lithium tetraborate," IEEE Trans. Ultras., Ferroel., Freq. Contr., vol. 45, No. 6, Nov. 1998, pp. 1506-1516. 16. S. Tonami, A. Nishikata, and Y. Shimizu, "Characteristics of leaky surface acoustics waves propagating on LiNbCO and LiTa03 substrates," Jpn. J. Appl. Phys., vol. 34, Part 1, No. 5B, May 1995, pp. 2664-2667. 17. Y. Kobayashi, N. Tanaka, K. Matsui, H. Okano, T. Usuki, K. Shibata, and Y. Shimizu, "1.9GHz-Band surface acoustic wave device using second leaky wave on LiTa0 3 and LiNb0 3 ," in Proc. IEEE Freq. Contr. Symp., 1996, pp. 240-247. 18. A. Isobe, M. Hikita, and K. Asai, "Propagation characteristics of longitudinal leaky SAW in Al-grating structure," in Proc. IEEE Ultras. Symp., 1997, pp. 17-21. 19. D. Zhang, X. Tong, and H. Qin, "Study of propagation properties of quasi-longitudinal leaky surface acoustic wave propagating on Y-rotated cut quartz substrates," in Proc. IEEE Ultras. Symp., 1999 (to be published). 20. G. Behme, E. Chilla, and H.-J. Frohlich, "Investigation of longitudinal leaky surface acoustic waves by scanning acoustic force microscopy," in Proc. IEEE Ultras. Symp., 1999 (to be published). 21. R. Veith, "The fabrication technology of Rayleigh wave devices," in Rayleigh-Wave Theory and Application, vol. 2, E. A. Ash and E. G. S. Paige, Ed., Springer series on Wave phenomena, Leopold B. Felsen, Ed., Germany, Springer-Verlag Berlin Heidelberg, 1985, pp. 254-272. 22. C. C. W. Ruppel, R. Dill, A. Fischeraurer, G. Fischeraurer, W. Gawlik, J. Machui, F. Miiller, L. Reindl, W. Ruile, G. Scholl, I. Schropp, and K.C. Wagner, "SAW devices for consumer applications," IEEE Trans. Ultras., Ferroel., Freq. Contr., vol. 40, Sep. 1993, pp. 438-452. 23. K. Yamanouchi and M. Takeuchi, "Applications for piezoelectric leaky surface waves", in Proc. IEEE Ultras. Symp., 1990, pp. 11-18. (see also practically all Proc. IEEE Ultras. Symp. from 1990 to date: several works and different authors). 24. I. D. Avramov, "Gigahertz range resonant devices for oscillator applications using shear horizontal acoustic waves," IEEE Trans, on Ultr. Ferr. and Freq. Control, vol. 40, no. 05, September 1993, pp. 459-468.

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25. M. Pereira da Cunha, "Effects of layer thickness for GSAW, PSAW, and HVPSAW devices," in Proc. IEEE Ultras. Symp., 1997, pp. 239-244. 26. M. Pereira da Cunha, "Effects of layer thickness for GSAW, PSAW, and HVPSAW devices," IEEE Trans, on Ultras. Ferroel. and Freq. Control, (to be published in 2000). 27. Eric L. Adler and Leland Solie, "ZnO on diamond: SAWs and Pseudo-SAWs," in Proc. IEEE Ultras. Symp., 1995, pp. 341-344. 28. D.L. Dreifus, R.J. Higgins, R.B. Henard, R. Almar, LP. Solie, "Experimental Observation of High Velocity Pseudo-SAWs in ZnO/Diamond/Si Multilayers," in Proc. IEEE Ultras. Symp., 1997, pp. 191-194. 29. I. S. Didenko, F. S. Hickernell, and N. F. Naumenko, "Theoretical aspects of GSAW and HVPSAW propagation properties for Zinc Oxide films on silicon carbide and correlation with experimental data," in Proc. IEEE Ultras. Symp., 1999 (to be published). 30. J. C. Andle, M. G. Schweyer, L. A. French, and J. F. Vetelino, "Acoustic plate mode properties of rotated Y-cut quartz," in Proc. IEEE Freq. Contr. Symp., 1996, pp. 532-540. 31. E. L. Adler, "SAW and Pseudo-SAW properties using matrix methods," IEEE Trans. Ultras., Ferroel, Freq. Contr., vol. 41, No. 6, Nov. 1994, pp. 876-882. 32. H. Goldenstein, Classical Mechanics, Addison-Wesley Publishing Company Inc., Cambridge, Massachusetts, USA, 1950, pp. 107-109. 33. A. J. Slobodnik, E. D. Conway, and R. T. Delmomco, Microwave Acoustics Handbook, vol. 1, Surface Wave Velocities, TR-73-0597, AD780172, NITS, Springfield, VA 22151,1972. 34. G. Kovacs, M. Anhorn, H. E. Engan, G. Visintini, and C. C. W. Ruppel, "Improved material constants for LiNb03 and LiTa03 ," in Proc. IEEE Ultras. Symp., 1990, pp. 435-438. 35. M. Adachi, T. Shiosaki, H. Kobayashi, O. Ohnishi, and A. Kawabata, "Temperature compensated piezoelectric lithium tetraborate crystal for high frequency surface acoustic wave device applications," in Proc. IEEE Ultras. Symp., 1985, pp. 228-232. 36. Yu. V. Pisarevsky, P. A. Senushencov, B. V. Mill, N.A. Moiseeva, "Elastic, piezoelectric, dielectric properties of La3Ga5 5Tao 5 0i 4 single crystals", in Proc. IEEE Inter. Freq. Contr. Symp., 1998, pp. 742-747. 37. M. Pereira da Cunha, "Surface and pseudo surface acoustic waves in langatate," in Proc. IEEE Ultras. Symp., 1999 (to be published). 38. G.W. Farnell and E.L. Adler, "Elastic wave propagation in thin layers," Physical Acoustics, vol. 9, W. P. Mason and R. N. Thurston, Ed., New York, Academic Press, 1972, pp. 35-127. 39. J. L. Bleustein, "A new surface wave in piezoelectric materials," Applied Physics Letters, 15 December 1968, pp. 412-413. 40. E. L. Adler, "Matrix Methods Applied to Acoustic Waves in Multilayers," IEEE Trans. Ultrason. Ferroelec. Freq. Contr., Vol. UFFC-37, No 6, November 1990, pp. 485^190. 41. M. Pereira da Cunha, "SAW propagation and device modelling on arbitrarily oriented substrates," PhD Thesis, McGill University, Montreal, Canada, July 1994.

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Pseudo and High Velocity Pseudo SAWs

1109

42. N. E. Glass and A. A. Maradudin, "Leaky surface-elastic waves on both flat and strongly corrugated surfaces for isotropic, nondissipative media," J. Appl. Phys., 1992, Vol. 54, no. 02, pp. 796-805. 43. B.A. Auld, Acoustic Fields and Waves in Solids, vols. I & II, Robert E. Krieger Publishing Company, Malabar, Florida, 1990, 2nd. edition. 44. G. A. Coquin and H. F. Tiersten, "Analysis of the excitation and detection of piezoelectric surface waves in quartz by means of surface electrodes," J. Acous. Soc. Amer., vol. 41, 1967, pp. 921-939. 45. R.C. Smythe, R.C. Helmbold, G.E. Hague, and K.A. Snow, "Langasite, langanite, and langatate resonators: recent results", in Proc. IEEE Inter. Freq. Contr. Symp., 1999, (to be published). 46. Eric L. Adler and Leland Solie, "ZnO on diamond: SAWs and Pseudo-SAWs," in Proc. IEEE Ultras. Symp., 1995, pp. 341-344. 47. D.L. Dreifus, R.J. Higgins, R.B. Henard, R. Almar, L.P. Solie, "Experimental Observation of High Velocity Pseudo-SAWs in ZnO/Diamond/Si Multilayers," in Proc. IEEE Ultras. Symp., 1997, pp. 191-194. 48. I. S. Didenko, F. S. Hickernell, N. F. Naumenko, "Theoretical aspects of GSAW and HVPSAW propagation properties for zinc oxide films on silicon carbide and correlation with numerical experimental data," in Proc. IEEE Ultras. Symp., 1999 (to be published). 49. V. P. Plessky and C. S. Hartmann, "Characteristics of leaky SAWs on 36° YX-LiTa03 in periodic structures of heavy electrodes," in Proc. IEEE Ultras. Symp., 1993, pp. 1239-1242. 50. V. P. Plessky, C. S. Hartmann, and J. Koskela, "Suppression of the leakage effect in 64° YXLiNb03 for thick aluminum electrodes," in Proc. IEEE Ultras. Symp., 1996, pp. 1603-1606. 51. K. Hashimoto, M. Yamaguchi, S. Mineyoshi, O. Kawachi, M. Ueda, G. Endoh, "Optimum leaky-SAW cut of LiTa0 3 for minimised insertion loss devices," in Proc. IEEE Ultras. Symp., 1997, pp. 245-254.

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International Journal of High Speed Electronics and Systems, Vol. 10, No. 4 (2000) 1111-1142 © World Scientific Publishing Company

SAW DEVICE BEYOND 5 GHz HIROYUKI ODAGAWA Research Institute of Electrical Communication, Tohoku University, Sendai 980-8577, Japan KAZUHIKO YAMANOUCHI Tohoku Institute of Technology, Sendai 982-8577, Japan Here we describe recent high frequency SAW technology based on ultra-fine fabrication techniques using electron beam (EB) exposure direct writing and low-loss wide-band filter applications beyond 5 GHz. We especially consider the propagation property of SAWs in the 10 GHz range, which is important for low-loss characteristics, the fabrication technology, and some examples of low-lossfiltersusing unidirectional transducers and ladder type SAW filters.

1.

Introduction

Surface Acoustic Wave (SAW) have been applied to electrical communication systems as various electronic devices, such as band bass filters, high frequency oscillators, convolvers, correlators, switching devices for optical applications, and so on. In mobile communication systems, SAW devices have been also applied and contributed the development. Now the frequency range of the mobile communication system is in the 2 GHz-range, and the SAW devices for the next generation mobile system are studied actively. Considering the remarkable increase of subscribers of mobile communication and the increase of the required date transfer rate, we can expect that the frequency range of mobile communication systems will be expanded to 5 to 10 GHz in the near future. Other applications, such as timing pick-up filters for light wave communication are also requiring devices in the 5 to 10 GHz-range. Accompanying the extension of the frequency range of the systems, SAW devices, which are important elements of electrical communication systems, must also expand their frequency range. Here we describe a SAW technology based on ultra-fine fabrication techniques for low-loss wide-band filters beyond 5 GHz. We especially consider the propagation property of SAWs in the 10 GHz range, which is important for low-loss characteristics and the fabrication technology. Moreover some examples of low-loss filter using unidirectional transducers and ladder type SAW filters are discussed.

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Propagation Loss in the GHz-Range for SAW Devices

It is necessary to estimate the losses in GHz-range SAW devices in order to obtain low-loss devices beyond the 5 GHz range. Especially, the propagation loss of SAWs up to the 10 GHz should be evaluated because the propagation characteristics is an essential physical property in SAW devices, and the loss in the 10 GHz-range is one of the greatest interests for SAW device engineers. In this section we describe the losses of SAW propagation in the GHz-range.

2.1.

Losses in SAW devices

The total insertion losses in SAW devices can be arranged according to different mechanisms ' as shown in Table 1.

Table I.

Losses in SAW Devices

Interaction with thermally excited elastic waves [Temperature dependent] Propagation loss due surface wave attenuation

to

Scattering by crystalline defects, impurities, and pits and scratches in the optical polish [Temperature independent] Energy lost to air adjacent to the surface [Pressure dependent]

Losses due to transducer configuration and geometry

Bi-directional loss using conventional two-IDT Diffraction of surface wave Conduction loss in electrode

Transducer loss

Spurious wave excitation loss Impedance mismatching loss

Among these mechanisms, propagation loss is the most essential to the SAW devices. The propagation loss is caused by interaction with thermally excited elastic waves (temperature dependent), scattering by crystalline defects, impurities, and pits and scratches in the optical polish (temperature independent) and energy lost to air adjacent to the surface (pressure dependent). The air loading loss is evaluated by measurements under low-pressure conditions. The temperature dependent propagation loss is evaluated by the change of the insertion loss from room temperature to lower temperatures.

246

SAW Devices Beyond 5 GHz

2.2.

1113

Measurement method for the propagation loss

In this section, the temperature dependency of the attenuation for a 10 GHz SAW propagating along the X-axis on 128° rotated Y-cut LiNb0 3 2,3 is described. The total insertion loss / of a two-transducer filter is given by ' / = EfAEfB

exp(-orP L),

(1)

where EfA and EfB are the transducer efficiencies of the launching and the receiving transducers (temperature dependent), ap is the surface wave attenuation per unit length and L is the distance between the transducers. If EfA and EfB have no temperature dependency, the attenuation constant aP is evaluated by the two-transducer system. Unfortunately, the variations of the EfA and EfB are large due to the temperature dependency of the resistivity on the transducer electrodes. Therefore, a three-transducer system as shown in Fig. 1 is necessary to evaluate the propagation loss. In this figure, the SAW excited from transducer A is received by transducers B and C. The ratio of the insertion losses is given by ^ ' B

= -^-exp{-ap(Lc-LB)}.

(2)

^ fB

In this equation, if the temperature dependency of Ef!/EfB is sufficiently small, av can be obtained by measuring the IB and / c . Therefore, if the temperature dependency of the insertion loss between transducer A and B (IB) and the loss between transducer A and C (/c) are measured as shown in Fig. 2(a), the difference between lB and lc, as shown in Fig. 2(b) does not contain the transducer characteristics. In Fig. 2(b), a, (-aP - a0) is the temperature dependent propagation loss caused by the interaction with thermally excited elastic waves, and a0 is temperature independent loss caused by crystalline defects, impurities, and pits and scratches in the optical polish.

LB B

Lc A

C

Fig. 1. Schematic diagram of 3-transducer.

247

1114

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Yamanouchi |

i

|

1

Loss (dB)

i

c o C oo c

a

1

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oc

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.

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(a) Propagation Loss (dB/unit length)

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.

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1

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(D

Temperature (K)

(b) Fig.2.

2.3.

Measurement method of the propagation loss.

Measurement results of propagation loss

The 3-transducer structure fabricated on 128° Y-X LiNb0 3 is used in the experiment. The wavelength of the transducers is X = 0.4 (im, and the propagation length LB and Lc are 105 X and 300 X, respectively. The pair number is 10, the aperture is 20 X and the film thickness of the Al electrodes is 30 nm. Table 2 shows the insertion loss of the 3-transducer device at room temperature (293 K) and at low temperature (7 K). In order to control the temperature, a helium flow cryostat is used. In this method, the sample space is directly cooled by temperature controlled helium. The measurement at 7 K is carried out after the sample is stabilized at 7 K for 1 hour, and then after the sample is warmed up to 293 K in a period of more than 3 hours, it is measured at 293 K.

248

SAW Devices Beyond 5 GHz 1115 Table 2.

Insertion loss of 3-transducer device at room temperature (293 K) and low temperature (7 K)

Frequency (GHz)

Propagation length (A.)

Insertion loss at 293 K

Insertion loss at7K

9.63

105

31.3

28.3

9.7

300

34.2

30.1

The experimental value at 10 GHz obtained from table 2 is plotted on Fig. 3. In this figure, the results at 1 to 5 GHz obtained in previous work 4 are also plotted. As shown in this figure, the attenuation (dBM,) is almost proportional to the 1.25 power of the frequency, and the propagation loss in the 10 GHz-range is about 1.5 dB / 100 X. This value includes the air loading loss and the temperature independent losses. This result shows that SAW propagation is low-loss even in the 10 GHz-range, and that SAW devices should be applicable in this frequency range. Figure 4 shows the frequency dependency of only the temperature dependent loss due to the interaction with thermal phonons. The new result at 10 GHz is obtained in the present experiment while the other results were obtained in Ref. 4. The loss (dB/cm) is almost proportional to the square of frequency. From these experimental results, we can conclude that the propagation loss and air loading loss are not the main contributors to the insertion loss in 10 GHz-range SAW devices.

0.020

1

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1

1

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,/

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0.005 0.004

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/0.33dB/10OA at3GHz "

§ 0.002 0.001 ,0.0008 - 0.08dB/100A at 1 GHz 1 2 3 5 7 10 Frequency (GHz) Fig.3. Frequency dependency of the propagation loss on 128° Y-X LiNbO? at room temperature.

249

1116

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Yamanouchi T

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3 GO

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2dB at 1GHz

OH

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5 10 Frequency (GHz)

Fig.4. Frequency dependency of the loss due to the interaction with thermal phonons on 128° Y-X LiNbOj at room temperature.

3.

Influence of Electrode Resistance in SAW Devices

In the previous section we confirmed that the propagation loss in the 10 GHz-range was small. The value was about 1.5 dB / 100 A,, which included the interaction with thermal phonons, scattering by crystalline defects, impurities, and pits and scratches in the optical polish, and energy lost to air adjacent to the surface. In this section, we describe the electrode resistance which largely affects the insertion loss of SAW device beyond 5 GHz-range.

3.1.

Influence of the resistance ofAl thin film in 8GHz-range SAWfilters

In order to consider the influence of the electrode resistance, filters using a floating electrode type unidirectional transducer (FEUDT) 5'6,7,8 are fabricated and measured at room temperature and low temperature. The structure and features of FEUDTs will be described in Section 5.1. Figure 5 (a) and (b) show the frequency response of a 8 GHz A.,/10 type FEUDT 8 at room temperature (300 K) and low temperature (7 K), respectively. These are result obtained at the second harmonic operation. ' The FEUDT is fabricated by electron beam exposure and lift-off process. The fabrication

250

SAW Devices Beyond 5 GHz

1117

techniques are described in the Section 4. The substrate is 128° Y-X LiNbO^, the wavelength at second harmonic is ^2=0-45 u.m and the propagation length is 46 A.2. The pair number is 20, the aperture is 46 A,2, the film thickness of the Al electrode is 30 nm, and the electrode width is 0.09 u,m. These frequency responses are obtained by using a time gate to reject the feedthrough of electromagnetic waves. The triple transit echo (TTE) is included in these results.

log MOG

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(b) Fig. 5. Frequency responses of a 8 GHz-range A.i/10-type FEUDT filter, (a): measured at 300 K, (b): measured at 7 K.

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Comparing both minimum insertion losses, we can see that the minimum insertion loss decreases at low temperature. The insertion loss at 7 K is about 8.5 dB, which is 3.4 dB lower than that at 300 K. Since the propagation length is 46 X2 in this case, the propagation loss due to the thermal phonons is only 0.26 dB according to Fig. 4. Therefore, the major reason of the decrease in the insertion loss is not caused by the propagation loss. Instead, we fined that the insertion loss is largely affected by the electrode resistance. Actually, this resistance, which is measured by DC voltage at 7K, decreases to 1/3 in comparison with its value at 300 K. This means that a reduction of the electrode resistance is very important to obtain the low-loss characteristics in the high frequency range. For example, the use of the wide electrodes, and the development of low resistance metal films are necessary to obtain low loss devices, especially beyond 5 GHz.

3.2.

Superconducting IDT using Nb thin film

One of the experiments to deal with the electrode resistance was carried out using a superconducting IDT electrode 2'3 instead of a conventional Al electrode. In this experiment, a Nb thin film is used in a 5 GHz-range Ji,/]0 type FEUDT filter. It is fabricated by electron beam exposure and lift-off technique described later. The substrate is 128° Y-X LiNbOj, the wavelength at second harmonic is ^.2=0.8 (im and the propagation length is 40^2- The pair number is 20, the aperture is 40^.2 and the film thickness of the Nb electrode is 100 nm. Figure 6 (a) and (b) show the frequency responses of the Nb FEUDT filter at 293 K and 5 K, respectively. Comparing both minimum insertion losses, we can see that the minimum insertion loss decreases at low temperature. The insertion loss at 5 K is about 13.3 dB, which is 12.1 dB lower than that at 293 K. The plots in Fig. 7 show the temperature dependency of the 5 GHz-range Nb FEUDT filter. The broken line shows the relative resistivity of the Nb film. As the temperature becomes lower, the insertion loss becomes lower, and finally, it changes markedly by about 2.2 dB at 7 K because the Nb resistance changes from normal to superconducting. The changes in the insertion loss and in the relative resistivity correspond well at the lower temperature. Although these results do not directly show that the superconducting Nb electrode is suitable for low-loss filters, they are important, because they suggest a direction of research on low loss filters beyond 5 GHz.

252

SAW Devices Beyond 5 GHz

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Fig. 6. Frequency responses of a 5 GHz-range X/10-type FEUDT filter using Nb electrodes, (a): measured at 293 K, (b): measured at 5 K.

253

1119

1120

H. Odagawa & K.

Yamanouchi

PQ

3 S/3

O

c o C

100 200 Temperature (K)

10 Temperature (K) Fig. 7. Temperature dependency of the insertion loss of a 5 GHz-range X/10-type FEUDT filter using Nb electrodes (a), and relative resistance of the Nb film (b).

4.

Fabrication Process

In the previous section, we considered some mechanisms for the insertion loss beyond 5 GHz. The next important concern for low-loss characteristics is the structure of the device. However, for discussing the device structure, we always have to consider whether a fabrication technique is available to realize the device structure. Therefore, before describing the structure of the filter, we describe in this section the fabrication technology for obtaining ultra-fine IDT electrodes around 0.1 (im.

4.1.

Fine lithography technology

SAW device can be fabricated by applying integrated circuit fabrication techniques using lithographic processes. Many types of fine lithography are proposed. Photolithographic techniques using the Hg-sourced G-line/H-line series to I-systems

254

SAW Devices Beyond 5 GHz 1121

(wavelength of 300 nm to 450 nm) have been developed, and are usually used in modern SAW device fabrication. A more developed method uses shorter wavelength ray sources, such as the excimer-based KrF (248 nm), ArF (193 nm) systems. Wavelengths of the above sources are shown in Fig. 8. In Ultra-Large-ScaleIntegration (ULSI) technology, the 0.18 u.m process has started using the KrF excimer laser. Now the next interest is 0.13 and 0.1 u.m technology. Especially, in the 0.1 u.m process, there are several selections, such as electron beam lithography, X-ray lithography using Synchrotron Orbital Radiation (SOR), and F2 excimer laser (157 nm) lithography. Within a few years, the techniques of the 0.1 u.m process will become the mainstream.

ultra-violet

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ArF

KrF

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visible

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.

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beam

.—•-

far-ultra-violet

g

h I

o

Intensity

P

1 100

200

_L 300

*

1 400

500

vavelength of generated l i g h t (nm) Fig. 8. Wavelength of the ray source.

4.2.

Electron beam exposure process for SAW applications

The direct Electron Beam (EB) writing techniques provide the finest line width, and an almost established technology to obtain 0.1 ^m-width electrodes. One of the drawbacks of the EB process is the throughput, because the conventional EB system uses only one focused electron beam to scan the exposure area. However, the size of the SAW device is inversely proportional to the frequency range of the device, and because it is suffices to use the EB lithography only for the interdigital electrode and it is not necessary to use for the bonding-pads and most of the lines for the electrical connection, which occupy the most of the area in the SAW device. The large area can be exposed by conventional photolithography after (or before) exposing or fabricating

255

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the interdigital electrodes by EB lithography. In this case the time to expose the IDT of one device is only a few seconds. Moreover, the writing speed of EB systems is increasing, and resist materials for EB are being developed. Therefore, it is just a matter of time before SAW device processing using EB lithography may be seriously considered for practical applications. Figures 9 and 10 show a flowchart of the etching and the lift-off techniques used for EB lithography. Each method has its own features. The most important feature of the etching process is that there are no limitations on the deposition of metal thin film for the electrode, such as deposition method and deposition temperature. Therefore, we can deposit the low resistivity metal film by the best method and the best condition available, and then we fabricate the electrode by etching. However in the etching process, the process parameters such as the etching rate of the metal film and the resist film, the determination of the etching stop as well as the process parameters in the lithography must always be carefully considered.

(1)

I

(2)

I Expose and Development

(3) Dry or Wet Etching

Fig. 9.

Flowchart of etching process.

256

SAW Devices Beyond 5 GHz 1123 On the other hand, with the lift-off process the electrode can be fabricated by a simpler procedure. In other words, the process parameters in lift-off process are fewer than that in etching process. When the inverse tapered resist pattern is obtained reproductively, the process is almost finished in the lift-off process. And the lift-off process does not cause the mechanical damage on the surface in contrast to the dry etching techniques. However, in the SAW device fabrication using EB lithography, the lift-off process requires additional film deposition to avoid charge-up by the electrons since the substrates of SAW devices are insulator materials. Figure 10(a) shows the case where a Cr film is used under the resist film, and Fig. 10(b) shows the case where an Au film is used on top of the resist film. 10 Both methods use the 0 2 plasma ashing technique.

10

Fine Al electrodes with a width of less than 0.1 u.m and a thickness of

about 30 nm were obtained both with the lift-off and the etching process. Figure 11 shows one of the Al electrodes for a 10 GHz-range ladder type SAW filter (described in Section 6), which is made by the lift-off process shown in Fig. 10(a), and the line and space width is 0.09 H-m.

EB exposure

Resist Development, 0 2 plasma ashing |. | *i^&smmmmmmmvmii

1

1

1 m>.:
^^^^^^t^t^^f^^^^^^^^m^i

Cr etching, 0 2 plasma ashing

Al evaporation

Lift off

Cr etching

Fig. 10(a). Flowchart of lift-off process for dielectric materials.

257

1124 H. Odagawa & K. Yamanouchi

E.BEAM

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Hi /

/

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Au (100 X)

•"•

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Fig. 10(b). Flowchart of lift-off process for dielectric materials.

258

SAW Devices Beyond 5 GHz

015906

20.0kV

X30.0K

1125

aa'enm

Fig. 11. Fabricated Al electrodes for 10 GHz-range SAW filter. (0.09 |im L/S)

4.3. Advanced fabrication process of narrow-gap structures using anodic oxidation techniques The electrode width of a conventional IDT with line and space ratio of 1:1 is A/4 as shown in Fig. 12(a), A being the wavelength at the center frequency f0. In contrast, the electrode width of a comparatively narrow gap IDT (NG-IDT) l0 shown in Fig. 12(b) is about A/2, and the operating frequency is twice that of an IDT using the same width of the electrodes. The operating frequency of NG-IDTs can, therefore, be increased, and the electrode resistivity reduced to about half that of conventional IDTs. Similar to the case of double electrodes, the reflections from the electrodes due to mass loading is reduced. Therefore, the narrow-gap structure is very useful for high frequency SAW

Fig. 12.

Structures of a conventional bidirectional transducer (a) and a

narrow-gap transducer (b).

259

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devices. Comparative narrow gaps can be obtained by separating the electrodes using an anodic oxidized film in the lift-off anodic oxidation method. Figure 13 shows the fabrication techniques using this method. The electrode separation using an anodic oxidized film is more reliable and has a better insulation between electrodes. It can be applied to the EB lithography process. An example of a fabricated narrow-gap electrode is shown in Fig. 14. " This Al electrode is made on 128° Y-X LiNb0 3 , and the period of the electrode is 0.16 urn and the thickness is 30 nm. This electrode works as a 12 GHz-range bidirectional transducer, and the experimentally measured insertion loss of the filter is about 16 dB, which includes the bidirectional loss and mismatching loss as shown in Fig. 15. In this case, because the transducers are bidirectional, the large ripple caused by the TTE appears in the pass band. However Fig. 15 shows that we can excite and receive efficiently the SAW in the 12 GHz range, and we can expect that low-loss and wide-band characteristics will be obtained if we use a unidirectional transducer. The filters using unidirectional transducers with narrow-gap structures will be described in Section 5. The narrow-gap structure and the fabrication process using anodic oxidation are useful techniques in GHz-range SAW devices.

RESIST

AUO

SUBSTRATE (a) Conventional etching, Anodic oxidation

SUBSTRATE (b)

Al evaporation

SUBSTRATE (c)

Lift off

Fig. 13. Fabrication process of narrow gap IDTs using the anodic oxidation technique.

260

SAW Devices Beyond 5 GHz 1127

n

r%. *% Tci Y > 3 ^ * •

iilllillliif:MllM^^ Fig. 14. Fabricated Al electrodes for a 12 GHz-range transducer using narrow gap structure.

1

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FREQUENCY [GHzJ Fig. 15. Frequency response of 12 GHz SAW filter using bidirectional transducers with narrow gap structure.

261

1128

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Yamanouchi

5. SAW Filter Using Unidirectional Transducer Beyond 5 GHz Conventional IDTs have an inherent minimum insertion loss of 6 dB because of bidirectionality and strong pass band ripple due to TTE. Moreover, in the high frequency range, the reflection of SAWs at the electrodes become large, causing multiple reflections of SAW in the IDT similarly to what happens in SAW resonators because the relative electrode thickness to the wavelength become large. As a result, the radiation efficiency decreases markedly, and wide band characteristics cannot be obtained for low-loss wide-band filter. Therefore use of unidirectional transducers is a practical choice. Important considerations for low-loss and wide band filters using unidirectional transducers beyond 5 GHz-range are a minimum electrode width, directivity, and radiation efficiency. The minimum electrode width is an important parameter from the viewpoint of low-loss characteristics, since a reduction of the electrode resistance is indispensable for low-loss devices. Moreover, from the viewpoint of the fabrication, the electrode width depends directly on the frequency limitation. The directivity and the radiation efficiency should be chosen by considering the total specification of the required characteristics. To study unidirectional transducers is very important, not only for achieving low-loss filters but also for the development of novel SAW devices, since there are certain characteristics that can only be achieved by unidirectional filters. Also such properties are indispensable in the SAW filter with good phase characteristics and functional device such as SAW convolver and switching devices for optical applications. In this section, we describe some low loss filters using unidirectional transducers beyond 5 GHz-range.

5.1.

FEUDT

One of the most practical unidirectional transducers which are applicable beyond the 5 GHz range is the FEUDT (Floating electrode type unidirectional transducer). 5'6'7'8 Generally, the frequency response of the FEUDT depends on the reflection coefficients of SAWs at the electrodes, which are caused by both mechanical and electrical effects. The A712 type FEUDT 5'6 shown in Fig. 16(a) has unidirectional characteristics mainly due to electrical reflection at the open and shorted floating electrodes. This type has good characteristics, but unfortunately, the electrode width is too narrow beyond the 5 GHz range. Also the 3^/10 type FEUDT 7 shown in Fig. 16(b) has good characteristics. This structure can excite SAWs efficiently in second harmonics operation. Therefore, the minimum electrode width is A,2/5 in second harmonic operation. Moreover, this type can be realized in narrow gap structure using anodic oxidation techniques as shown in Fig. 16(c). 8 I ° However, the characteristics of this

262

SAW Devices Beyond 5 GHz

1129

structure largely depend not only on electrical reflection but also on mechanical reflection at the electrodes. Therefore, an increase of the electrode thickness results in a too large directivity because of the increase in the reflection coefficient with increasing film thickness. A large directivity produces a large variation of the admittance, which causes a ripple in the main lobe of the frequency response. Generally, when the mismatch at an electric port is large, the reflection of the SAW at an acoustic port of the receiving transducer increases with increasing directivity. Therefore, a directivity with a value of around 7 dB is preferred in the FEUDT to x,

(a) r

«=•

|S-*|

|6

x,

3 x,

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10

(c) <>

-*-

2X<

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Structure of FEUDT.

263

1130

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Yamanouchi

obtain low ripple characteristics. Since thin electrodes make the insertion loss large, thick electrodes relatively to the wavelength are required beyond 5 GHz. It is necessary to use a A.|/l0 type FEUDT which corresponds to a suitable directivity for the thick electrode beyond the 5 GHz range. 8 Figure 16(d) shows the configuration of a X\/\0 type FEUDT. This transducer also works efficiently in second harmonic operation. It has a symmetrical arrangement of electrodes in terms of the mass loading effect, with a directivity that does not depend very much on the electrode thickness. Moreover, this A.,/10 type FEUDT is advantageous in terms of fabrication, especially for electron beam lithography, since all the ratios of line to space are 1.0. The electrode width is X2/5 in second harmonic operation. Figure 17(a) shows a frequency response of the X^/10 type FEUDT filter working in second harmonic operation in the 8 GHz range. This filter is made by the lift-off process. This is a connecter-to-connecter characteristic. Al wire bonding is used to connect the electrical port to the SMC connectors. The length of the Al wire is chosen to cancel the susceptance in the electrical port of the transducer. This characteristic includes the TTE signal while the feedthrough signal is rejected by time gating. Figure 17 (b) shows a Smith chart of this filter. The electrical matching is not satisfactory as shown in this figure. The insertion loss will be reduced when the electrical matching is carried out completely. The substrate is 128° Y-X LiNb0 3 , the wavelength at second harmonic is ^2=0.45 |i,m and the propagation length is 46A,2. The pair number is 20, the aperture is 46X.2) the film thickness of the Al electrode is 30 nm, and the electrode width is 0.09 |a.m.

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A/4 electrode thickness difference type SPUDT

An electrode configuration similar to that of the conventional 2 fingers/A. IDT is also applicable for high frequency single phase unidirectional transducers (SPUDTs), since the 2/A. IDT has the highest radiation efficiency and wide electrodes. This is important from the points of view of the fine pattern fabrication and for decreasing the electrode resistance. In order to realize such SPUDTs, electrodes of different thickness are useful because they shift only the center of reflection while the radiation efficiency remains high. We have previously reported some practical fabrication processes for electrodes of different thickness. 1213 Figure 18(b) is an electrode thickness difference type SPUDT (ETD-SPUDT) u with an electrode pattern width ofk/4. Figure 18(a) shows a split finger IDT which has unidirectional characteristics due to the difference in the reflection coefficients of the electrodes of different thickness or different material. The mechanism of the unidirectionality for this transducer has been described by Hartmann and Wright. 15 It has high efficiency, and the fabrication for the GHz range is easy if electrochemical fabrication techniques are used. I2 On the other hand, Fig. 18(b) is a narrow gap version of Fig. 18(a) made using anodic oxidation techniques. The mechanism of the unidirectionality is the same as that of the structure in Fig. 18(a), and the radiation characteristics are the same as those of the conventional narrow gap IDT. This IDT is well suited for the high frequencies since the electrode width of the structure in Fig. 18(b) is twice that of the structure in Fig. 18(a), making the electrode resistance approximately half that of the

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the conventional 2 finger/A, IDT.

fn\

(a)

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if

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r

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+

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(a) Split finger type,

! + \ (b) XIA type.

The fabrication process of the X/4 ETD-SPUDT is shown in Fig. 19. Only the X/4 line and space processes are used, and no accurate alignment exposures are required. One of the fabrication processes is as follows. (a) (1) An Al film with a thickness of h, (Al-1) is evaporated onto the piezoelectric substrate and resist patterns (main electrode patterns) are formed on the Al-1. (2) The Al-1 film is etched by conventional wet or dry etching, and Al electrodes (Electrode 1) are fabricated. (3) Without removing the resist pattern, anodic oxidation is carried out in order to make an A1 2 0 3 film for electrical separation of the + and the - electrodes. (b) (4) A second Al film with a thickness of h2 (A 1 -2) is evaporated from an oblique direction ' 6 shown by the arrow in the figure, without removing the resist film. (5) The areas in the shadow of the resist, which are shown as white areas in Fig. 15(b), are not evaporated by the Al film. (c) After that, a lift-off process is carried out. (d) Electrodes 1 and 2 are connected when a thick Al film for bonding pads is fabricated by a lift-off process and the desired structure is obtained. Experimental results obtained using 128° Y-X LiNb0 3 substrate and Al electrodes are as follows. Figure 20 is a scanning electron microscope (SEM) micrograph of the electrodes of the fabricated 5 GHz range X/4 ETD-SPUDT. The period of the electrodes is 0.185 (im. In this case, the thickness of Al-1 and Al-2 are 60 nm and 45 nm, respectively.

266

SAW Devices Beyond 5 GHz 1133 /K\

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Fig. 20.

SEM micrograph of the Al electrode of 5 GHz-range A/4 ETD-SPUDT.

Figure 21 shows the directivity of the A/4 ETD-SPUDT measured in the 500 MHz range as a function of the pair number (N) for various film thicknesses. It shows that an IDT with 40 finger pairs has a large directivity (more than 8 dB) within the practical thickness range.

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Figure 22 shows the frequency response of a 5 GHz range X/4 ETD-SPUDT filter. The Al thicknesses are 70 nm (9.5 % of the wavelength) and 50 nm (6.8 % of the wavelength), and the pair number is 30. This characteristic is extracted from the experimental S parameter measured by a microwave probe, assuming that ideal matching circuits are added at the electrical ports. In this case, a minimum insertion loss of 5.6 dB is obtained in the 5 GHz range. 10

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268

SAW Devices Beyond 5 GHz 1135

6.

Ladder Type Filter

Another type of SAW filter, called ladder type filter, 16 does not rely on SAW propagation, but instead uses SAW resonators as impedance elements. Using ladder type filters, low-loss characteristics have obtained beyond the 5 GHz-range. ' ' In this section, low-loss ladder type filters in the 10 GHz-range are described. In order to study the characteristics of a ladder type filter from equivalent circuit model analysis, we determined the parameters of the equivalent circuit experimentally, as no studies have been carried out on the reflection characteristics of SAWs for thick electrodes. Figure 23(a) shows the admittance characteristic of a 5 GHz-range SAW filter using a A/4 width conventional bidirectional IDT on 128° Y-X LiNb0 3 . The finger pair number of the IDT is 18, the aperture is 30 X, and the thickness of the Al film is 60 nm (0.08A.), where X is 0.75 urn. Large ripples are caused by the reflection in the receiving IDT. We determined the parameters by fitting the calculated results to the «EF 6 . 0 Limits 3.0 ntlnits'' •v

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bidirectional IDT. (a) experimental, (b) calculated results.

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experimental results. First, the susceptance B s , which represents phase shifts caused by the energy storage effect and the piezoelectric shorting, 20 is determined as the center frequency is fitted to experimental results, and then the normalized acoustic impedances of the electrodes (Zm) is determined as the admittance characteristics are fitted to the experimental results. Figure 23(b) shows the calculation results. In this case, Bs is 0.16 and Zm is 1.064. Figure 24 shows the structure of the ladder type filter. It has 6 SAW resonators which have reflectors of 20 strips with widths of X/4 at both sides of the resonators. However, the effects of the number of gratings are small because the reflection coefficients of the electrodes are large. The parameters are shown in Table 3. The ratio of the static capacitance of resonator A to that of resonator B is 1.7. The frequency response calculated using the obtained equivalent circuit parameters is shown in Fig. 25.

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Table 3. Parameters of the ladder type filter in 10 GHz.

Pair number

Aperture

Period (wavelength)

Resonator A

120.5

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0.38 urn

Resonator B

100.5

lO.OXs

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SAW Devices Beyond 5 GHz

1137

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1.00 1.05 Normalized Frequency

1.10

Calculated frequency response of the ladder type filter.

The micrograph of the electrodes in resonator A observed by SEM was shown in Fig. 11 in Section 4.2. The electrode width is 95 nm, and the thickness of the Al film is 30 nm (0.079k). They are fabricated on 128° Y-X LiNb0 3 using the electron beam exposure system and the lift-off process. The resolution of the EB system is 40 to 50 nm and the minimum step of the beam scan is 10 nm in the setting of this experiments. Because of the limitation of the scan step, we use the structure shown in Fig. 26 (b) as the resonator B for the purpose of adjusting the resonant frequency of resonator B to the antiresonant frequency of resonator A. Figure 27 shows the frequency responses of the 10 GHz-ladder type filters. They are measured by microwave probes. A low loss characteristic with a minimum insertion loss of 3.4 dB is obtained as shown in Fig. 27(a). Figure 27(b) shows the characteristic of another filter. A considerable reduction by 25 dB of the electromagnetic feed-through is obtained in the 17 GHz range. The reduction characteristics in the high frequency range largely depend on the structure of the connection electrodes and the structure of the bonding pads. It is necessary to optimize the structures. These results show the feasibility of SAW devices for communication systems in the 10 GHz-range.

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(a)

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(b) Resonator B.

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272

SAW Devices Beyond 5 GHz

7.

1139

Prospective

In this paper, we described the recent progress in high frequency SAW technology based on the ultra-fine fabrication using EB direct writing techniques. On the other hand, other approaches using high-speed substrates have also been studied and have shown promise for achieving SAW device beyond 5 GHz-range by means of optical lithography. For example, diamond thin film on Si substrate, 2I'22 longitudinal leaky surface wave on Li 2 B 4 0 7 23 and other materials have the possibility to beyond 5 GHz devices without using EB lithography. In order to realize the 10 GHz-range SAW devices commercially, issues such as electromagnetic feedthough rejection, the durability of the electrodes, the electrode resistance, and fine electrode fabrication techniques should be studied. These are important issues not only for the SAW devices, but generally for high frequency miniaturized devices. However, especially in SAW devices, the substrate is a dielectric material, which sometimes has a high dielectric constant. The design technology that will be required in 10 GHz range does not lend itself to a separate evaluation of the IDT characteristics and the packaging, but must instead be based on a 3 dimensional analysis of the electromagnetic field of the total device, which includes both the substrate, the IDTs and the packaging. By optimizing the total device structure, we will be able to achieve a sufficient electromagnetic feedthough rejection. In fact, we experimentally obtained the 50 dB suppression of the feedthough signal for propagation distance of 100 X at the 10 GHz. Furthermore, advanced trimming techniques will also be required in 10 GHz-range, especially when relatively narrow band characteristics are required.

8.

Conclusions

We described SAW device techniques for the 5 to 10 GHz range based on ultra-fine fabrication techniques. The recent advances show that the SAW device technology has reached a level at which practical applications should be considered up to the 10 GHz range. Several approaches may be applied to achieve high frequency SAW devices. Here is shown how SAW devices fabricated by EB lithography may be approaching sufficient maturity to be considered for practical applications.

273

1140 H. Odagawa & K. Yamanouchi References 1. A. J. Slobodnik, P. H. Carr and A. J. Budreau, "Microwave Frequency Acoustic Surface-Wave Loss Mechanism on LiNb0 3 ", J.Appl.Phys., Vol.41, No.l 1 (1970) 4380—4387. 2. K. Yamanouchi, "Generation, Propagation, and Attenuation of 10 GHz-Range SAW in LiNbO,", 1998 IEEE Ultrason. Symp. Proa, Vol.1 (1998) 57—62. 3. K. Yamanouchi, H. Nakagawa, J. A. Qureshi and H. Odagawa, "10 GHz-Range Surface Acoustic Wave Low Loss Filter Measurement at Low Temperature", Jpn.J.Appl.Phys., Vol.38, No.5B (1999) 3270—3274. 4. K. Yamanouchi, "GHz-Range SAW Device Using Nano-Meter Electrode Fabrication Technology", 1994 IEEE Ultrason. Symp. Proc, Vol.1 (1994) 421—428. 5. K. Yamanouchi and H.Furuyashiki, "New Low-Loss Filter Using Internal Floating Electrode Reflection type of Single-Phase Unidirectional Transuducer", Electron. Lett. Vol.20, No.24 (1984)989—990. 6. M. Takeuchi and K. Yamanouchi, "Coupled Mode Analysis of SAW Floating Electrode Type Unidirectional Transducers", IEEE Trans. Ultrason. Ferroelec. Freq. Contr., Vol.40, No.6 (1993) 648—658. 7. K. Yamanouchi, M. Takeuchi, T. Meguro, K. Doi and K. Murata, "Wide Bandwidth Low Loss Filter Using Piezoelectric Leaky SAW Unidirectional Transducers with Floating Electrodes", Jpn. J. Appl. Phys., Vol.30, Supplement 30-1 (1991) 173—175. 8. K. Yamanouchi, C. S. Lee, K. Yamamoto, T. Meguro and H. Odagawa, "GHz-range Low-Loss Wide Band Filter Using New Floating Electrode Type Unidirectional Transducers", 1992 IEEE Ultrason. Symp. Proc, Vol.1 (1992) 139—142. 9. K. Yamanouchi, Y. Cho and T. Meguro, "SHF-Range Surface Acoustic Wave Interdigital Transducers Using Electron Beam Expusre", 1988 IEEE Ultrason. Symp. Proc, Vol.1 (1988) 115—118. 10. K. Yamanouchi, T. Meguro and K. Matsumoto, "Surface-Acoustic-Wave Unidirectional Transducers Using Anodic Oxidation Technology and Low-Loss Filter", Electron. Lett. Vol.25, No. 15 (1989) 958—960. 11. H. Odagawa, N. Tanaka, T Meguro and K. Yamanouchi, "Submicron Fabrication Techniques

Using Electro-Chemical

Effects

274

and

Application

to Unidirectional

SAW

SAW Devices Beyond 5 GHz 1141 Transducers", 1994 IEEE Ultrason. Symp. Proc, Vol.1 (1994) 437—440. 12. H. Odagawa, T. Kojima, T. Meguro, Y. Wagatsuma and K. Yamanouchi, "GHz-Range Conventional )J4 Unidirectional Surface Acoustic Wave Transducers and Their Application to Low-Loss and Zero-Temperature Coefficient Filters", Jpn. J. Appl. Phys., Vol.36, No.5B (1997) 3087—3090. 13. H. Odagawa, T. Meguro and K.Yamanouchi, "5 GHz Range Low-Loss Wide Band Surface Acoustic Wave Filter Using Electrode Thickness Difference Type Unidirectional Transducers", Jpn. J. Appl. Phys., Vol.35, No.5B (1996) 3028-3031. 14. C. S. Hartmann, P. V. Wright, R. 1. Kansy and E. M. Garber, "An Analysis of SAW Interdigital Transducers with Internal Reflections and Application to the Design of Single-Phase Unidirectional Transducers", 1982 IEEE Ultrason. Symp. Proc. (1982) 40—45. 15. K. Yamanouchi, Z. Chen and T. Meguro, "New Low-Los Surface Acoustic Wave Transducers in the UHF Range", IEEE Trans. Ultrason. Ferroelec. Freq. Contr., Vol.34, No.5 (1987)531—539. 16. T. Nishihara, H. Uchishiba, O. Ikata and Y. Satoh, "Improved Power Durability of Surface Acoustic Wave Filters for an Antenna Duplexers", Jpn. J. Appl. Phys., Vol.34, No.5B (1995) 2688—2692. 17. H. Odagawa and K. Yamanouchi, "10 GHz-range Extremely Low-Loss Surface Acoustic Wave Filter", Electron. Lett. Vol.34, No.9 (1998) 865—866. 18. H. Odagawa and K. Yamanouchi, "10 GHz-Range Extremely Low-Loss Ladder Type Surface Acoustic Wave Filter", 1998 IEEE Ultrason. Symp. Proc. (1998) 103—106. 19. S. Lehtonen, V. P. Plessky, M. T. Honkanen, VOvchinnikov, J. Turunen and M. M. Salomaa, "SAW Impedance Element Filters for 5 GHz and beyond", 1999 IEEE Ultrason. Symp. Proc. (1999)395—399. 20. K. Kojima and K. Shibayama, "An Analysis of Reflection Characteristics of the Surface-Acoustic-Wave Reflector by and Equivalent Circuit Model", Proc. 7lh Symp. Ultrasonics, Kyoto 1986, Jpn. J. Appl. Phys., Suppl.26-1 (1987) 117—119. 21. K. Yamanouchi, N. Sakurai and T. Satoh, "SAW Propagation Characteristics and Fabrication Technology of Piezoelectric Thin Film / Diamond Structure", 1989 IEEE Ultrason. Symp. Proc. (1989)351—354.

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22. A. Hachigo, H. Nakahata, K. Itakura, S. Fujii and S. Shikata, "10 GHz Narrow Band SAW Filters using Diamond", 1999 IEEE Ultrason. Symp. Proc. (1999) 325—328. 23. T. Sato and H. Abe, "Propagation Properties of Longitudinal Leaky Surface Waves on Lithium Tetraborate", IEEE Trans. Ultrason. Ferroelec. Freq. Contr., Vol.45, No.l (1998) 136—151.

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International Journal of High Speed Electronics and Systems, Vol. 10, No. 4 (2000) 1143-1191 © World Scientific Publishing Company

WIRELESS SAW IDENTIFICATION AND SENSOR SYSTEMS F. SCHMIDT and G. SCHOLL Siemens AG, Corporate Technology Surface Acoustic Wave Technology and Wireless Systems Otto-Hahn-Ring 6, 81730 Munich, Germany

Identification and sensor systems based on surface acoustic waves exhibit intriguing properties which have hitherto remained unexploited by semiconductor-based systems. They offer a long readout distance of up to more than 20 meters with purely passive surface acoustic wave (SAW) devices. SAW devices operate with no battery or wiring, withstand extreme temperatures and work reliably and maintenance-free over many decades even in harsh industrial environments. Because they operate at frequencies in the GHz range, SAW identification and sensor systems are well protected from the electromagnetic interference that often occurs in the vicinity of industrial equipment such as motors and high-voltage lines. The fundamentals and design rules of numerous passive wireless SAW sensor and identification systems for industrial and domestic applications as well as relevant practical work will be presented.

1. Introduction Surface acoustic wave (SAW) filters play a key role in consumer and communication systems thanks to their high performance, small size and high reproducibility.1 These properties also make them attractive for identification and sensor applications.2'3 Generally, any problem will have several technological approaches and various solutions. It is therefore vital to focus on the specific advantages offered by SAW devices. Their most outstanding property is clearly that they can operate with no wire connection or battery over long distances, as they are connected only by a radio frequency link to a transceiver or reader unit.4"9 This is due to the fact that SAW devices can operate even with very low signal levels at their input. In contrast, semiconductor-based devices require a fixed minimum voltage to operate, thus drastically limiting the range of passive coupled ID tags to about 0.5 meters. In this article, wireless SAW sensor and identification systems will be discussed and various interesting applications will be presented. A schematic drawing of a wireless sensor/identification system is shown in Fig. 1. A high-frequency electromagnetic wave is emitted from an RF (radio frequency) transceiver which is basically a low-cost radar unit.10 This radio wave is received by the antenna of the SAW sensor/ID-tag. The comblike interdigital transducer (IDT) shown in Fig. 2 is connected to the antenna and transforms the received signal into a SAW which propagates along the piezoelectric crystal and is partially reflected by reflectors placed in the acoustic path. The reflected waves are reconverted into an electromagnetic pulse train by the IDT and are then retransmitted to the radar unit. The received signal is amplified and down-converted to the baseband frequency in the RF module. The sensor signals are then analyzed by a digital signal processor. Finally, the measurement results are transferred to a PC or another device for post processing, data storage or to perform specific tasks.

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1144 F. Schmidt & G. Scholl

SAW ID tag

Antenna

Transceiver unit Fig. 1. Schematic drawing of a SAW identification/sensor system. The velocity of a SAW is lower than that of electromagnetic signals propagated in free space by a factor of approximately 100,000. Signals can consequently be efficiently delayed by a small SAW chip. A delay of 1 |_is requires a chip length of only between 1.5 and 2 mm (the path length between the IDT and the reflector is used twice), depending on the substrate material, whereas radio signals in free space propagate 300 m in the same time. The pulse responses of SAW sensors can thus be delayed by up to several microseconds. This enables them to be separated easily from environmental echoes, which typically fade away in less than 1-2 (xs. If the reflectors are arranged in a predefined bit pattern such as a barcode, an RF identification system can be implemented with a readout distance of several meters. By analyzing the fine structure of the response signals, SAW radio ID and sensor systems can also be applied to the measurement of chemical or physical quantities. In the first part of this article, radar-type sensor and identification systems such as those shown in Figs. 1 and 2 will be discussed. Antenna SAW Chip

Transmitted pulse

A») (JUUVLA.

(«

Reflector

SensorfTag response

Fig. 2. Schematic drawing of a SAW reflective delay line. However, such a radar-based system has two drawbacks. Firstly, not many ID tags or SAW sensors can be located within the detection range of the transceiver at the same time. If more than a few sensors are present, their response signals superimpose at the receiver and can no longer be separated. And secondly, the detection range of about 10 meters, although sufficient for many applications, is rather limited.

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Receiver unit Fig. 3. Schematic drawing of an event driven sensor/identification system.

To overcome these two main restrictions, we have developed a different kind of SAW sensor. The basic idea is that, as sensed processes often involve remarkable amounts of energy in the form of mechanical pressure change, movements or torque forces, temperature change etc., why not simply use this energy to operate the sensor instead of supplying it via radio waves? Consequently, the sensor type described from Section 4 onward does not reflect radar signals but generates its own RF signals with energy drawn from the sensed process as shown in the schematic drawing in Fig. 3. The sensor still makes use of SAW elements. The only difference compared with the radartype sensor is the origin of the requesting RF signals, which in this case are generated in the sensor itself. We have called it the event-driven sensor.

2. Passive Wireless SAW ID Tags and Sensors Although the first physical and chemical sensors based on SAW devices were reported in the early 1970s, considerable active research is still under way. ' The basic design of reflective delay lines for wireless identification and sensor systems generally follows the same principles as those established for classical SAW filters. An additional difficulty is that many sensors cannot be sealed hermetically like conventional filters but are exposed to the influence of external perturbations. In the case of physical sensors, an applicationspecific packaging and mounting technology must often be developed. Fortunately, these difficulties do not exist for SAW ID tags. Another advantage is that except for the coding process, the same fabrication techniques as those used for RF SAW filter manufacture can be adopted. Thanks to this compatibility with standard fabrication processes and to the potential size of the high-volume markets for automotive manufacturing, trailer and container tracking, as well as car and personnel access, we believe that SAW identification systems have a very good chance of market success and will pave the way for other SAW-based wireless sensor systems.

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2.1 SAW ID tags Like all wireless communications systems, SAW identification systems must operate according to the radio frequency regulations. The ISM (industrial, scientific and medical) band at 2.45 GHz with a bandwidth of 100 MHz is an internationally available frequency band compatible with SAW technology. Although another ISM band at 433.92 MHz is available and is often used for remote entry systems in the automotive industry, its bandwidth is limited to 1.7 MHz. It is consequently not well suited for SAW ID systems, especially when a large code space is required. Modern RF filters for cellular phones typically employ leaky waves and surfaceskimming bulk waves13"15 on high coupling substrates for the three following reasons. The high electromechanical coupling coefficient allows efficient interdigital transducers and reflectors with only a small number of electrodes and therefore a broad bandwidth to be implemented. Because of the high velocity of leaky waves, the line widths that have to be implemented become greater. The power durability is also much higher than for Rayleigh waves. Although the first two arguments are also relevant for ID tag designs, the most important parameter of an ID tag is its insertion loss, especially at 2.45 GHz. As a result, the well-known classical Rayleigh wave substrates LiNb03-YZ and LiNbOy rotl28° are generally used. However, even on these substrates the propagation loss is 6 dB/us at 2.45 GHz. The propagation loss at 433 MHz is a negligible 0.25 dB/us, whereas that at 900 MHz is approximately 1 dB/us. Which substrate is finally chosen will depend on the specific design and on the specifications which have to be satisfied, so that tradeoffs will have to be made. Basically, there are two ways of arranging the reflectors. Either all the reflectors can be positioned in different tracks (Fig. 4), or several reflectors can be lined up in only a few tracks (Fig. 2).16,17 In the first case, all the reflectors can have 100% reflectivity and thus totally reflect the incoming wave. In the second case, the reflectivity has to be decreased in order to make it homogeneous for all the reflecting elements. The problem of multiple reflections must also be taken into account, thus limiting the dynamic range of on/off-coded ID tags. The optimum number for a 2.45 GHz tag was calculated in Ref.19 as eight reflectors per track. Although the reflectivity of the reflector positioned next to the IDT is typically reduced to -20 dB, we found that a design with multiple reflectors in one track can nevertheless be attractive, especially when a large code space is desired. If the reflectors are placed in different tracks, problems with diffraction effects and track loss arise. Large apertures are desirable in order to minimize diffraction effects, but these lead to problems with the impedance level. On the other hand, if the transducer aperture satisfies the requirements of the termination impedance, the reflector apertures can be smaller than an acoustic wavelength. Millions of RF filters are manufactured every day for cellular phones. More than a thousand fit onto a 3-inch wafer and one dozen are exposed at a time. SAW delay lines are based on the efficient delaying of RF signals. The size of SAW ID tags is thus limited by the required code space, which results in a reduced number of chips/wafer. If on/off coding is selected as the modulation scheme and a code space of 32 bits is required, then 34 reflectors are needed. Two of them, one start and one stop reflector, are generally used for temperature compensation. If each reflector of the tag is also structured with a wafer stepper, the number of exposures required to structure the same number of chips is three orders of magnitude greater than that for an RF filter. It is therefore vital to reduce the number of reflectors and to develop an economical coding process. Phase coding represents one way of doing this.18

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Wireless SAW Identification

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Fig. 4. Reflective delay line with only a single reflector per track.

Figure 5 shows the measured time-domain response of a 433 MHz ID tag with quadrature shift keying. Although phase-coded tags can be implemented easily at 433 MHz, material and fabrication tolerances prevent the use of this technique at 2.45 GHz. The solution is to use pulse position modulation, in which the information is given by the relative position of the reflectors instead of the phase. The time-domain response at 2.45 GHz of a SAW ID tag with 18 reflectors and a code space greater than 232 is presented in Fig. 6. The tag was measured with a network analyzer and then ideally matched to 50 Q. It can be seen that the insertion loss is approximately 53 dB. Excellent amplitude uniformity was achieved. The time-domain response of a 20 bit ID tag at 2.45 GHz with on/off-keying is shown in Fig. 7 for comparison.

100 CD

0

2,

CD CO co

sz a.

I-

2

4

6

-100

8

time [us] Fig. 5. Time-domain response of a phase-coded ID tag at 433 MHz.

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-40

3 4 time [us] Fig. 6. Time-domain response of a pulse-position coded ID tag at 2.45 GHz.

-*0

time [us] Fig. 7. Time domain response of an on/off-coded ID tag at 2.45 GHz.

2.2 Binary SAW sensors and programmable reflectors The first ID tags with on/off-keying were designed with open or short-circuited reflectors, the coding being implemented by either structuring a reflector or not. This involved the inherent problem that the uniformity was affected and code-dependence occurred because the attenuation and bulk wave conversion differ depending on whether a reflector is present or not. A solution was to replace an "off reflector with a nonreflecting structure having the same transmission and bulk-wave conversion loss as the "on" reflector.19 In order to allow the reflector to be dynamically changed from "on" to splitfmger transducer can be used for this component (Fig. 8). If the reflector is open circuited, the transducer reflects an incoming wave. If the reflector is shorted, hardly any reflection occurs. The first and last reflectors in Fig. 8 are shortened to reduce end-effects which generate unwanted reflections when the reflector is "off.

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Fig. 8. Splitfinger reflector with shortened end electrodes.

In Ref. 21 a prototype of a train-control system was implemented in which a reflective SAW delay line with nine splitfinger reflectors was embedded in a commutator network in hybrid technology (Fig. 9). The last reflector was kept permanently "on" to maintain function control. After a trigger burst from the reader unit, an 8-bit data word was transferred from the memory to the commutator network. According to the logical state of each bit, the corresponding reflector was switched "on" or "off and an 8-bit data telegram was retransmitted to the reader unit. Thanks to the coherent storage of the energy in the SAW device, no synchronization was necessary between reader and transponder so that a very high data rate could be achieved.

R

c

L

Fig. 9. Switching network for SAW reflector.

In Fig. 10 a Reed element is connected to a reflective element of a binary SAW sensor. If the sensor is accelerated beyond a specific value, the magnet moves and causes the Reed contact to change from the open-circuited state to the short-circuited state or vice versa.

Reed Element Fig. 10. Binary SAW sensor with switchable reflectors.

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In the left diagram of Fig. 11, all three reflectors have almost the same reflectivity. In the right diagram, the third reflector is shorted by the Reed element. A change of approximately 30 dB in reflectivity can be observed. Sensors of this type can be used as sectoralignment indicators, for checking switch positions, or generally as radio-access switches. In the same way, classical sensors with varying impedance can also be read out in wireless mode when combined with a SAW transponder as in Ref. 22, as will be shown in Section 2.4.

-40

open

-60

-80

2"'

i ' • '' 1

li k

time [lis]

6

7

L

-80 2

8

3

4

5

6

7

8

time [jis]

Fig 11. Time-domain response of a binary SAW sensor with switchable reflectors.

2.3 SAW temperature sensors A change in the environmental temperature AQ results in a variation of the path length 31 and the SAW velocity 3v. Accordingly, the propagation time T changes to

T ~ 1/30

v90

T3 = T C D , A T 3 ,

(1)

where TCDi represents the first-order temperature coefficient of the delay. This equation can be generalized for other physical or chemical sensors to AT

(2)

where the sensitivity S of y to a change z is defined by

^ = liml-^ = i . ^ AZ-»O y

\z

y

(3)

az

The term 31/1 represents the mechanical strain, which can also be caused by factors such as the direct application of a mechanical force or electrostriction. The second term in Eq. 2 is produced by a change in the material parameters. Either effect can be dominant, depending on the geometry and the substrate material. For instance, when YX-LiNbC>3 is subjected to a biasing electric field, the strain contribution exceeds the velocity by far, whereas on YZ-LiNb03 with a delay temperature coefficient of 85 ppm/K the thermal expansion coefficient is an order of magnitude smaller than the temperature coefficient of the velocity. A SAW temperature sensor with four reflectors and a center frequency of

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433 MHz mounted in a standard SMD package is shown in Fig. 12. The time domain response of an equivalent temperature sensor at 869 MHz is depicted in Fig. 13.

Fig. 12. SAWtemperaturesensor with four reflectors mounted in an SMD package.

The readout distance is approximately 0.5 m. The time delay is 2.5 p . The sensor pulses are separated by 0.84 |is, 0.7 ps and 0.73 |is respectively. The reflectors were designed for high reflectivity in order to achieve a low return loss of 28 dB. Consequently, the pulses following the four main response peaks, which are due to multiple reflections between the reflectors themselves and between these and the IDT, are suppressed by only 15 dB. To evaluate the temperature value, the phase variations of reflected pulses A