Temperature dependence of the raman linewidth and frequency shift in Ge and Si

Temperature dependence of the raman linewidth and frequency shift in Ge and Si

TEMPERATURE DEPENDENCE OF THE RAMAN LINEWIDTH AND FREQUENCY SHIFT IN Ge AND Si S. Francis Bitter National Magnet and B. LAX SAFRAN Laboratory+ ...

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TEMPERATURE DEPENDENCE OF THE RAMAN LINEWIDTH AND FREQUENCY SHIFT IN Ge AND Si S.

Francis

Bitter

National

Magnet

and B. LAX

SAFRAN

Laboratory+ and Physics Department, Cambridge, MA 02139, U.S.A.

Massachusetts

Institute

of Technology,

(Received 7 Ocroher 1974) Abstract-Information about the anharmonic properties of crystals can be obtained from a study of the temperature dependence of the linewidth and frequency of their Raman spectra. We have calculated the frequency shift of the zone-center optical phonon in silicon and germanium as a function of temperature assuming that the lifetime and self-energy of the k = 0 optical phonon is governed only by decay into two LA phonons. We find that our model not only fits the experimental data for the frequency shift, but is also highly consistent with calculations and experimental data for the linewidth. The consistency in the fining of the theoretical curves thus obtained to the experimental data, determining the same, single adjustable parameter for both the shift and the width seems to corroborate the view that there is a selection rule. aside from momentum conservation, which limits the optical phonon decay into two LA phonons only.

1. IhTRODUCTlON

Raman

where

scattering

due

the spectral

frequency linewidth

which

lo phonons

Here

lines have a finite vary

with

width

temperature.

and shift can be understood

is the unperturbed

eigenvalue

p signifies principal

part.

Recently,

and peak

The

EI

subscript

results in a spectrum

linewidth

other states of the system1 I]. Similarly,

assumption

interactions.

in systems with

such as phonons

have

in an anhar-

optical

has been calculated (0)

from

into two LA

the

which

shifts in the Raman dependence of the

by Klemmens[3]

that it arises only

phonon

H,,and

been performed

and frequency

spectra of Ge and Si. The temperature

as arising from the

finite lifetime of a state due to spontaneous emission into dissipative

experiments

measure the linewidths

natural

of

on the

the decay of the

phonons

of balanced

manic crystal, we can also expect a finite width and shift

momentum. This has been confirmed by the experimental

due to interactions

data of Hart el ol. in Si[4] and by Ray et al. in Ge[5]. In

arising from “collisions”

phonons. Using perturbation

theory,

between the

this paper, we extend

Brout [2] has calcu-

lated the width and shift due to interactions

frequency

of the form

this approach

shift, similarly

and calculate

the

assuming that the only decay

channel is 0 -+ LA - LA and compare our results with the

H = H, + HR -F H,,,

(1)

experimental

data in both Si and Ge. In addition,

demonstrate

and

the consistency

ing the normalizations H,=H,,+AVwithIhVIGHo

(2)

linewidth

H, is the Hamiltonian due lo the radiation field; H,.,represents the interaction between system and radiation; H, is the system Hamiltonian where H,,

where

describes the system without

interactions

and V couples

the modes of the system as in collision

techniques

and who evaluated

quency shift numerically allowed,

the difference repopulation

in the frequency and depopulation

a set of quantum

&

shifts or linewidths

due 10 by

the linewidth

(3a) and the O+ LA +

of temperature.

systems,

CALCL’LATIOZ

the dissipative

resented by V in equation

rep-

three phonon process[8] k

P

v = c c(k, k’,k”) WL’ II I-

is given by

&-r .,‘.

(a,, - a:,)(a,.K - a:.k)(a,-,--

=~~ll’~(~~-~,~)where s is the branch index,

I-k

a:-,-)

(4)

(3b)

number by the National

interaction

(2) is due to the anharmonic

(3a)

is the shift of level k, while the linewidth

Qupported

and fre-

mentioned above, and a linear approxima-

2. PERTL’RRATIOS In phonon

by k, where

=$Fyygf k

that of

are given by

of a state characterized

numbers represented

shift and the from

assuming all decay channels are

in that we use equation

shift as a function shift and the linewidth

differs

tion lo the LA dispersion relation to obtain the frequency

effects. The total frequency

Our work

Cowley [6] and Maradudin [7] who used Green’s functions

LA restriction

and anharmonic

for both the frequency

calculations.

we

of our approach by compar-

Science Foundanon.

of

anharmonic 753

atoms

in

coefficient,

the

k = the wavevector, crystal,

c(k,k’,k”)

N is the is the

and II,~ and u ;* are the annihila-

754

S. SAFRAN and

tion and creation operators for phonons on branch s with wavevector k, where (n + Ilu’ln) = J&

(n + 1)“’ (5)

(n - l]aln) = J&(n)“’

Here, M is the atomic mass and n is the occupation number of that mode. In our calculation, we shall only consider the difference in the terms in equation (4) corresponding to the creation or destruction of one optical phonon of frequency w0and the simultaneous destruction or creation of two acoustic phonons. The other terms in equation (4) give rise to either non-energy conserving terms in the case of the linewidth or either non-resonant denominators or cancellations in the expression for the shift given by equation (3a) in our approximation of decay to two phonbns~belonging to the same branch. Thus, we consider only V, =

2 ~(0, k, -k)aoa:~,a:--t

(6)

,‘I x

Vz= c c(0, k, -k) a,,+a,,ra,- t 7’l.L

B. LAX

where y is the Griineisen constant which is assumed to be frequency independent. In order to equate AE due to this strain to the energy of the anharmonic term, we calculate S(o*) from (9) and (II), considering terms to first order in e only; thus $3 remains the same and (1 +x)-l is approximated by I - X. The results give S(o*) proportional to w2 and S(L)=

-21rsw’

(12)

0

Using this expression in (8) and equating coefficients of the displacements due to the strain and ao, we find: ~(0, k, -k) = coo*/2

(13)

A more careful analysis, using the exact dispersion relation]lO] for unit maSS

o2 = a + /3 + d/(a + /3)’ -4a/3 sin*ka

(14)

and calculating 8(0’) again to first order in e by expanding the radical in equation (14) assuming

(7) (15)

where a0 refers to the k = 0 optical phonon and because of the delta function in equation (4), k’ = -k” = k. In order to approximate the frequency dependence of the c(k,k’k’? terms, we shall extend an argument presented by Klemmens [3,9] and estimate c(k, k’, k”) by equating equations (6) or (7) with the energy due to a static strain identical to the instantaneous strain field of the optical mode in its interaction with the acoustic phonons. Since the energy of an acoustic mode k is given by Mo’a’(k)a(k), (the a (k) may be thought of classically as referring to position), a strain causes a change in energy d AE = d(~2) [Mda+(k)a(kj]

1

6(wL)

(8)

yields o’+ 6(w2) =(aotPo)+2~~(uo-Bo)-~

(16)

which reduces to, upon the use of the expression for the optical mode frequency obtained from equation (14) at k ~0, 00 = 2(ao + 83,

Also, because the dispersion relations for Si and Ge resemble those of a three dimensional “linear” chain with atoms of the same mass with different force constants /3 and a, we write as a first approximation[3]. o2

2i:

--!!!k

sin’ko

(9)

a2

(17)

which agrees with equation (9) for small (o/w,). Therefore, from equation (13a)

(a+BW ~(0,k, -k) = coo2f(o/wo)

(18)

1 f(w/oo) = - (1 - 2~z/00’)“ 2

(19)

Imposing a strain e, where where Au ET-

a (Au is the atomic displacement and a is the lattice parameter) and where the strain is +z on every a link and --E on every /3 link, we get a = &(I +2ye) (11) /.?= P,(l -2ye)

Noting, as above, that we want the difference between the squares of matrix elements of VI calculated between (T~.~t Iv$~-~+ Ino = 01 and ]ns.t~,--tq~ = 1) and those of V, evaluated between (nl.k - lnr--k - 1 no= 11 and l~.~n,-_~n~= 0), the expression for the linewidth and the frequency shift become upon using equation (5) in

155

Temperature dependence of the raman linewidth

equation (8) above,

we shall make the approximation that

A = $ & co?f(&‘o)12 (o,_;~~w:;~“_,) x

r = $zk

(v+k

c,2Lf(w/wL#ws’kws”-k

-

+

8(

w,,

+

1)

+

-

1)

w$k

(vs”k

-

-

1)

w,“k)

(21)

where the population of the k th mode on branch s is given

by risk= [exp($)-lr’

(22)

Since we are assuming decay into two LA phonons only and are excluding all. other channels, we can use the Debye approximation which is applicable considering the linear nature of the LA branches of Si and Ge [ 11,121.We thus set o = vk and consider decay to only the LA branch, summing over all wave-vectors on that branch. We therefore drop all sums over s and s’ and set wssK= wssrK.In addition, in order to obtain an analytic expression for A and I, we let &sd3k=

T=I

I

&$w2dw

Since coth x is being integrated this approximation should not result in any serious error. In doing the integration we take care to note the relationships between x, 2x,, and 1 in order to perform correctly the principal part integration which can be integrated by standard analytic methods. In addition, in order to proceed with the integration in equation (25a), we take f2(o/wo) out of the integral and evaluate it at some average value of w/wO.Since, as we demonstrated above, the important part of c (0, k, -k) is the w2 dependence-this shows up even in the approximate dispersion relations-we should be justified in leaving the w2 dependence of c(0, k, -k) in the integral and taking out f’(w/w3. For convenience we define

6-4 Since f is determined by the ratio of two frequencies, its temperature variation can be neglected. The results of the integration of equation (25a) are, with y = 4kT/hwo and y,,, = 4kT/hw,

(23)

Thus, our expressions for the width and the shift become A=k,,@

I

--$&

Lf(&&

(26a)

coth x =

(20)

1) -;dk?,.“-k)

[($‘k

7js’k?s”k]

{(%‘k

(TIC+ 77-k

+

1)

F(Y)

do

A(T) = - Aocuoflyy,,,z 2

(27a)

A(T) = - AaflF(y) y,,,%2

(27b)

= [ y4+2y3~pgi-12Yt(y-l)lnll-yl+P,]

(284

(24a) r=2rko

CW I

0~4Lf(W/Wo)l* (qk + 7-k

+

1)

~(WO -

2w) do where (24b)

,=%=yo

where

00

c,’

~o=~z3t2z2+2r+ln/2z-1/

and is the same for both linewidth and the frequency shift with n7s8K = n7s,rKas above. Defining x = ho/2kT and x0 = hwo/4kT, we get for the shift

I

O*Xm Lf(w/o,,)]’&

coth x dx (25a)

while the trivial integration of equation (25b) yields for the width I = 27r& coth xo= Tocoth xo

(25b)

where ho again, is the same for both I and A. The integration in equation (25a) is carried out by integrating from zero up to xm = hw,/4kT which corresponds to the maximum frequency of the LA phonon-approximately the zone-edge frequency. In order to perform the integration in (25a) analytically, JPCSVol. 36No.7-I

(294

v 4rr

kc,=--7 h (2rr) v

A= -A,@-$

ym

po=(Y0t4z4

(29b) (29~)

We therefore see that the physical interpretation of AO is that A(0) = - A$F(O) = - A$j% is the zero temperature shift due to the self energy of the optical phonon, where /lo is given by equation (29~) and f by equation (26b). Similarly, in the case of the linewidth, from equation (25b) r(O) = I0 = 2rA0 is the zero temperature width. At finite temperatures, considering z > l/2, the shift is negative and linear with T for high temperatures, while for low temteratures, it is determined by F(y) which -PO for 0 < y < 1, if we expand the log term to 4th order. 3. RESULTS AND COMPARISON WITH EXPERIMENT

Equations (27)-(29) give the frequency shift as a function of temperature in terms of only one undermined positive parameter & = A$ which is proportional to the shift

756

S.

SAFRAN

and B. LAX

and the width at T = 0. To determine A& we fit our curves to the data of Ray et al. for Ge [S] and Hart et al. for Si [4] using values of z and w0 described below. The parameter was determined equation

using a least squares fit for

(27a) and equation

determining

each of

(27b) for all T < 700 K and

the final value of h; by taking a weighted

average of the values obtained from the fits. For Ge this gave Ab = 0.61 cm-‘,

while

check for consistency, data using equation

for

Si AI, = I.58 cm-‘.

As a

the fits to the high temperature

(27a) and the low temperature

using equation

(27b) were done separately-the

pancy in &was

less than IO per cent in both materials.

data

discre-

Since from equation (27b) we see that there is a finite shift even at zero temperature,

we had to determine

a

suitable value of w”, different from the values given by the data

at zero

temperature.

By

extrapolating

T = 0 K from the high temperature,

back

to

linear regime, we see

that values of w0 = 309 cm-’ for Ge and 532 cm-’ for Si are appropriate.

These “unclothed”

and turned

values of on were used

out to give the best tit to the experimental

data[l3]. The parameter

z = w,,/u,, was taken as 0.82 for Si and

0.80 for Ge. This is in line with our decay model; the LA

K/Kmo,.

Fig. 2. Phonon dispersion curves for Ge in the [It I] direction obtained from neutron scattering (after 8. Brockhouse[ 121). The value of w, lo, = 0.80 was obtained as in Fig. I caption.

branch is highly linear in both Ge and Si with a maximum w,,,, determined by the k/k,,,

frequency, straight

line fitted

to the dispersion

= 1 intercept of a curves for the LA w.

branches and averaged over the three principal directions. Since z is a ratio dependence

of two frequencies

-I

GERMANIUM = 309 cm-’

,

its temperature

can be neglected. (See Figs. I and 2).

Our plots of the shift A(T), along with the original data points of Hart et al. for Si [4] and Ray et al. for Ge [S] are presented

in Figs.

considering

3 and 4. The fits are satisfactory

the approximations

discrepancies

used. In particular,

at high temperatures

can be attributed

the

-

to

200

r-

---1

-GY

---I

04

06

08

Id

K/Km,,

Fig. 1. Phonon dispersion curves for Si in the [ 1001 direction obtained from neutron scaftering (after G. Dolling[l I]). The value of w, Iw, = 0.82 was obtained by approximating the LA branch by the dashed line and averaging values of w, for various directions.

600.

800

SIL!CON

-.200

02

1 (%I

Fig. 3. A plot of the frequency shift of the Stokes component of the first order Raman line in Si, as a function of temperature. The x signs represent the data points of Hart er a/.[41 and thesolid line is the curve obtained from equation (27) of the theory assuming only two LA phonon decay. See text for explanation of dashed line.

0

-0

400 TEWERATURE

Fig. 4. A plot of the the first order Raman x signs represent the is the curve obtained only two LA phonon

L_. 400 TEMPERlTURE

..I 600

I300

rK)

frequency shift of the Stokes component of line in Ge as a function of temperature. The data points of Ray er al. [5] and the solid line from equation (27) of the theory assuming decay. See text for explanation of dashed line.

Temperature

multiphonon around

processes.

traced

to the error

x = I leading this bump dashed

the

lack

in F(y) there.

terms

proportional

the frequency

parameters

agreement the data

much

better

linewidth

our

by a

than

the low

use equation

dependence The

of

temperature

fit

values

of the frequency

the simpler

calculation

(?Sb), indicates

for the shift,

shift

A(O) = - A$F(O) = 1 for

As

noted

equation determine

f

of

i’

x (z’)‘.

= - &of&,

average

Thus,

the

with

I

0

f =

To

for

p(z’)z’ d:’

Si in our

in equation

~ = 42

(32)

d:’

approximations,

and

flu as

to equations

(30) and (31) we see that,

both the linewidth

due to the 0+2LA consistent satisfy

decay

calculation the

and the frequency of

following

as we have both

r(T)

assumed, and

relationship

if in

shift are only

when

then a

A(T)

should

evaluated

at

T=OK: -2a

r(o)

= -0.37Ge

m=m

for Ge[ 141 is r(0)

PI(O) = -3.Ocmwho found equation

from Thus,

[r(O)/A(O)]

(33) evaluated

= 2.

calculate

A(O) = - 8.5 cm-’

ture data as above, excellent

implying

agreement agree

proper

choice

which

gave

addition adjustment

with

so well best

to satisfying of wa when

we estimated

that with

from

fits

Similarly.

[r(O)/I(O)]

fitting

= - 0.25, again in (33)

That

the

is due to the

we chose were the ones

to the

equation

we

low tempera-

(33) above.

equation

for Si,

pt al. [4] while

the actual

equation

with

we get et al.[S],

= 0.37 in agreement

by Hart

of w,)- the values the

while

by recent

while

of Ray

for germanium.

as indicated

I cm-’

as measured

= I.1 cm-‘.

the data points

= 0) = 306 cm-’

w(T

o0 = 309cm-‘.

(33)

= -0.26Si

The T = 0 value of the linewidth experiments

results

structure,

approxima-

that are in good

The values

of r(O)/b(O) data

are

and

ef al.[4]

phonon.

some

to determine

conservation

phonons,

experimental

that there

which

the the

is some that only

operates

in the

We suggest that besides work

further

in crystals theoretical

those possible

selection

of the work

be

rules.

Ackno&dgemtnts-We wish to thank Dr. R. Aggdrwal for several useful discussions, and Drs. T. Hart and P. G. Klemmens for discussions of their previous work. We are also grateful to Dr. V. J. Tekippe who provided us with recent values of the low temperature linewidth in Ge prior to publication. REFERENCES

Returning

r(0)

further

curves

momentum

of the optical

the

only into two

All this seems to corroborate

to two LA

pursuing

only.

of both

decays

experimental

by Hart

rule besides

diamond

phonon

the

calculations.

first suggested

undertaken

calculation decay

(29~) is given by 5.37 for Ge and 5.82

for Si. reality

both

decay

in the

in Ge and Si, assuming

yields

experiment.

relaxation

we get

branch,

for

selection

two LA

and using a Debye-type

with

allows

z’ = w,,,/o~ as above,

optical

agreement

the first

states

of a consistent

assumes

the

function

of

fitting

4. CONCLL’SIOSS we note that calculations

phonons

tion for the LA

view

which as the

shift and the fits in the case of the

which

that the zone-center

theoretical

evaluating

I .79 for Ge and 2.05 for Si. since z = 0.80 for

and 0.82

defined

by

of z’ = w/w~.

points

(33) for both the theory

shift and the linewidth

same

the

et al.141 and Ray et a/.[51 were not merely

In conclusion,

longitudinal

satisfied

fits as well

that our curve

but are the results

on a model

of z’, we calculate

p(z’)

yielding

calculation]

value

based

density

value

using

2’ =

Ge

(31)

is approximated

at some

the correct

moment p(z’)

above,

(19)

by Hart

frequency (30)

temperature

implies

case of the frequency

that if we

then at T = 0

w = 00/2 in the width

of our fits to the data

same values of the ratio in equation

width

have

to fit.

both good finite

of the

l-(O) = I-” = 27r&

Lf2(w,/wo)

consistency

and the experiment,

overall curves

The

we would

8% in Ge and 12% in Si where

data was more difficult yielded

(33). if not in

had we used our curves

data points,

(33) to within

fortuitous,

in equation

(27b)

&,

totally

[6].

(2Sa) with

resulting

have

equation

with equation

For example,

and not the actual

around

indicated

calculations.

of our calculation

equation

agreement.

and the low temperature

by Cowley

Comparison

are in good agreement

exact

that

and temperature

in all

is gratifying

calculated

which

We believe

We

157

Si can be

our constant,

to y’/c’.

of the raman linewidth

agreement

in the coth x approximation

to the bump

is not real and is, therefore,

neglected these

of

T = 200 K for

line in Figs. 3 and 4. In addition,

contains

from

while

T = 120 K for Ge and

dependence

experimental

(33).

However,

the data

leads

data

in

even

an

to results

I, Wigner E. and Weisskoff V.. Z. Phvsik 63. 54 (1930). !. Brout R., Phps. Rec. 107. 664 (1957). 3. Klemmens P. G.. Php. Rer. 148. 845 (1966). 4. Hart T. R.. Aggarwal R. I.. and Lax B.. Ph.vs. Rer. B. I. 638 (1970). 5. Ray R. K.. Aggarwal R. L. and Lax B.. in Proceedings of the Se&d /nte&rional Conference on Light Scat&n~ in Solids. (Edited hr Balkanski M.) n. XX. Flammarion Science. Paris (1971). . 6. Cowley R. A., 1. Ph,vs. (Paris) 26. 659 (196.0. 7. Maradudin A. A.. Fein A. E. and Vineyard G. H.. Phvs. Stat. Sol. 2. 1479 (I%?). of the Theory of Solids D. 68. 8. Ziman J. M.. in Princinles Cambridge University Press, Cambridge il9??). ’ 9. Klemmenb P. G.. in Solid Store Physics. (Edited by Seitz and Turnbull). Academic Press. h’.Y. (1958). p. 33. Let a-l/M. l/M,+@ and I/M,-+P IO. See reference[gl. lo get our expression. Symposium on rhe II. Dolling G., in Proceedings of International Inelasric Scartering of h’eurmns in Solids and Liquids. Vienna. I%?. Vol. ?. D. 37. International Atomic Aaencv. _ _ Vienna (1963). B. N.. 1. Ph.vs. Chem. So/ids 8. 402 (1959). I?. Brockhouse 13. Hart Tim. Ph.D. Thesis. Massachusetts Institute of Technology (1970 unpublished). On p. 70. Hart suggests a value of 529cm ’ for Si. 14. More recent measurements by Tekippe V. J. and Aggarwal R. L. on Ge at low temperatures down IO 4.2 K yield a value of I ‘I cm ’ for r(O) in contrast to the value of I .4 cm-’ deduced _ m reference 5 (prlvale commumcatum).