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A calculation of the elastic constant c33 of a graphite crystal as a function of temperature
A CALCULATION OF THE ELASTIC CONSTANT Cl,., OF A GRAPHITE CRYSTAL AS A FUNCTION OF TEMPERATURE B. T. KELLY UKAEA Reactor Fuel Laboratories,
Springfields Works, Salwick, Nr Preston, Lancashire, England
(Received
1973)
5 November
Abstract-A calculation is presented of the elastic constant CM of a graphite crystal as a function of temperature up to 2500 K, taking into account the anharmonic contribution and the changes in interlayer interactions due to the large lattice thermal expansion. Parametric variations in the theory show that the anharmonic contribution to G depends principally on the parameter (a’C,,/~e~,). Comparison of theoretical results with the experimental data, which is mainly from neutron scattering experiments, shows that the data can be accounted for if (a*CJae~,) lies in the range 7-10 X 10” dynes/cm*. A theoretical estimate of (a’C,,/ae?,) based on Lennard-Jones potentials between atoms in adjacent basal planes gives a value of 9.07 X lOI dynes/cm?. 1. INTRODUCTION Measurements highly
of the
oriented
natural
which
by
Shirane[5]
theoretical
up
variation
of the
if we know e,, as a function
variation
inter-
of C& as a function A
number
of the interlayer published[lO-131
forces and
has been
shown [12, 131 that pair potentials
vided
of
value
of C,,[12,
that
of in
tuted
it
can be used to calculate
the
of temperature,
in
anharmonic
of
effects
in
these
are small. If the values of Cs, and obtained in this way are substithe
thermal
Kelly and Walker
expansion
500°K [17]. The
theory
of
[ 151, much too large a varia-
tion of cr, with temperature neutron
is obtained scattering
above
data [4-91
indicate that Css does not decrease as rapidly with increasing temperature as the simple
first derivative with respect to strain e,, parallel to the hexagonal axis. These potentials the
ac-
of C& and (a C,,/a eLZ)with strain e,,;
parameters (aC,,/ae,,)
the Lennard-Jones and Buckingham types readily account for the value of CJJ and its
for
to
be accurately
then CQ3 and (aC,,/ae,,) can also be estimated as a function of temperature, [16, 171, pro-
and
have been
2200°K.
potentials[lO-131
of neutron
have
account
could
showed
(Y, parallel
counted for using the theoretical values of CQJ and (G,/ae,,) at 0°K. The interlayer
ap-
graphite
cannot
axis
zero.
Brockhouse
been
hexagonal
meas-
Roy [4],
to
the
coefficient
at absolute
studies
studies
values
paper [ 151 the author
the expansion
to be any direct
and others[6-91
temperature
that
tempera-
However
to yield values
In a previous
and
to be good
of the temperature
constants.
scattering preted
at ambient
to the values
and
Seldin good
and suggestions have recently been made that C4 is largely electronic in origin [14].
of
graphite
produced
constants
do not appear
urements elastic
have
constants
of Some,
are also believed
proximations There
crystals
[l-3]
for the elastic ture
pyrolytic
graphite
co-workers
elastic
131
theory of the change of interlayer forces with strain indicates, and thus either the constants
.535
536
B. T. KELLY
in the pair potentials are actually temperature dependent or the anharmonic contribution to Css is significant. There may also be anharmonic effects in (aC,,/ae,,), but the only experimental data is at ambient temperature. The purpose of this paper is to calculate the variation of Css with temperature, including both the effect of strain on the interlayer forces and the anharmonic contribution.
and, therefore,
from (3) (5)
Substituting Equation spectively gives
(1) in (3) and (5) re-
4. THEORY Consider a unit cube of graphite crystal with the c-axis parallel to a cube edge which is also the z-axis of a Cartesian coordinate system. The free energy/unit volume of the cube is written as [18]: F = E + kTx
i
In (1 - exp [- hu, /kT]),
(1)
where E k h vi
is the lattice energy/unit volume is Boltzmann’s constant, is Planck’s constant, is the i’th lattice vibrational frequency. The summation is to be taken over all lattice vibrational modes in unit volume. The thermodynamic relation between pressure P and free energy F is p=_
( > _g
*
(2)
T
The volumetric strain of a graphite crystal is essentially the same as the interlayer strain e PI, so that to a good approximation, P is equivalent to a stress a,, parallel to the hexagonal axis, i.e., (3) By definition, (4)
and
exp (-h/kT) [l - exp (-hvi/kT)]*
’
(7)
In order to evaluate Equations (7), we need the values of the lattice frequencies pi and their first and second derivatives with respect to stram eZZ. The acoustic mode lattice vibration frequencies are given in the Komatsu [19] semicontinuum model of the lattice dynamics of graphite by analytic expressions. The theory of the thermal expansion coefficients of graphite crystals developed by Kelly and Walker[15] and refined by Kelly[ZO] shows that only one vibration mode, the out-ofplane acoustic mode, is significantly modified by strain eZZ_The dispersion relation of the mode is:-
where p is the density, CT~and a, are the wave number components parallel and perpendicular to the basal planes, and 6 is the bond bending coefficient as defined by Komatsu [19]. The differentials of the dispersion relation (8) are:
GRAPHITE
The
calculations
cient
CRYSTAL
of thermal
(Y, [20] indicate
AS A FUNCTION
expansion
that (&Y/ae,,)
tively small effect compared
method
coeffi-
has a rela-
to (8 G/a
ezL_)and
537
OF TEMPERATURE
due to Crowe11[23]
riate
pair potentials
tion
over
in which approp-
are summed
a uniform
atomic
(a&/de,,). The parameter S is a property of the intra-layer covalent bonds which cannot
layer. We assume
a Lennard-Jones
be much
tween
in adjacent
thus
affected
we assume
lected
that
e%,). With
strain
(a’s/ae?,)
by comparison
(a%,,/8 tions
by interlayer with
these
e,, and
assumptions
(9) and (10) reduce
rated
may be neg-
(a’C,,/ae%)
atoms
by a distance
by integra-
density
in each
potential
layers
only,
besepa-
r
and Equa-
(13)
to:
I
+$’ P
a (12)
The values of (aC,,/ae,,) and (aC,,/ae,,) are known from the work of Spain et al. [21] but it
is a constant.
is necessary
over a uniform
mate at the
in order
(a*E/de:,),
to evaluate
(d’C,,/de:,),
interlayer
spacing
(7), to esti-
and (a’C,,/aeZ,) corresponding
to
where
plane
from
Thomas-Fermi to provide
calculations
estimates,
[22].
If Equation
following
energy/unit
0°K. Each of the above values may be estimated from atomic pair potentials between atoms in different layer planes[lO-131 or order
A is the Van Der Waals constant density
(T of atoms
Crowe11[23],
volume
and rll
(13) is integrated the
in a basal interlayer
is
E =v[;
(2)“-
11,
(14)
In
we will follow the
where
No is the number
of atoms/unit
volume
538
B. T. KELLY
and d the interlayer spacing. The equilibrium condition for the crystal at O”K, with interlayer spacing d = do, is C3E
(ad>d=4=0)
(15)
and by using d, = 3.3535 x lo-@ cm C&d,) = 3.67 X 10” dynes/cm*. In the same way we obtain
and
($?)d_d..
(20)
= d,“(j$)d;d”
= -l%s(do),
which yields r,,== 2d:.
(16)
The energy E at a spacing d different is readily found to be
from do (%)d=do
E(d) =+GV#$-+I. The elastic constant given by
1d4
($=d’(s) =!+_)[1~(!%)6_5](~)Y
(19)
The value of Equation (19) at a temperature T”K is obtained by substituting the value of d for natural graphite at that temperature [24],
0 exp {(h/k~)(4~~3*~,4 1- exp {- (h/k~)(4T’~‘u,4
((
= 251Css(d,).
-1,4d,
+ (C,,/pm2d,2) sin’ 7rd,uZ + (C~lp)c~?“*} + (Css/p,r*d2) sin’ rdOgz + (C+JP)~~)~‘~I I
C44 CQ3 sin’ rr d,u, + a,’ 47r262u,4 + 2 pn d, P C44 sin’ r d,c+, + - ua2 P (I-
exp {-- (hlkT)(4r 26 ‘aa4 + (Css/p,r2d02)sin2 Td,u, f (Cti/P)Ua’)“‘} exp {- (h/kT)(4,r*62u2+ (CQS/pr2d:) sin’ Ird,uZ + (cdPb~)“2))*
x 1 [(sin’ ~d,a,lp~*d,‘)(aCQQ/aell) + (~~21~)(acdae=)12 4 [4T262~,4 + (Css/pr2d,*) sin’ rrd,u, + G/P)u~I
which is our principal
result.
(21)
Experimentally [21] (a CM/ae,,) = - 6C44 but it is not possible to estimate (aC,/ae,,) or (d*CJae%) from the Crowell model because the assumption of a uniform atomic density in the basal planes reduces the shear resistance, and hence CM, to zero. However we note that the numerical coefficient of CSs in the equation for (#C,,/aeL) is roughly the square of the numerical coefficient of C& in the equation for (aC,,/?Je,,) and, making the same assumption for the parameters associated with shear, choose (L!‘C,,/deE,) = 35& for initial calculations. The final equation for CSs on conversion of the second term of Equation (7) from a summation to an integration over the first Brillouin zone is
0 (W
= = 12V;:No.
The first term in Equation (7) at a spacing d different from d, corresponding to temperature T”K is
’
= d,‘(j$)d_dQ
(17)
C&3at 0°K (i.e. d = d, is
C&d,) = d,2 $j [
which is to be compared with the experimental value[21] of - 15Css, and
da, I)
. due.
GRAPHITE 3. NUMERICAL
Equation
AS A FUNCTION
CRYSTAL
OF TEMPERATURE
EVALUATION
(22) is of the form
(23) where we refer to A(T) as the anharmonic contribution. The expression for A(T) in Equation tion
(23) was programmed
on a computer
Central
Technical
using
the following
by Mr
for
evalua-
M. Toes
Services
of the
numerical
of the UKAEA
values.
Numerical value
Parameter
6.623 x 10mz7 Ergs/set 2.46 X IO7 cm-’ 3.3535 X lo-” cm 2.26 gmicc 1.380 x 10-‘h Ergs/deg 6.11 X lo-” cm2/se6’ 3.67 X 10” dynes/cm’ 4.00 x 10” dynes/cm’ - 15G5 = - 5.5 x 10” dynes/cm’ - 6Cs4 = - 2.4 X 10” dynes/cm* 251C,, = 9.0’7 X 10’” dynes/cm’ 36C,, = 1.44 X 10” dynes/cm*
h (T,,,
d,,
P k
6
G C14 (aCk/de,,) (aG/de,J (dYk/deb)
(a2C.dae~,)
Fig. 1. Anharmonic
ature
value of
A (T) as a function
is shown in Fig. 1. The calculated
of Cs, as a function pared
of temperature
with the experimental
The (a’C,Ja
effect
of variation
e:,) and (a’C,,/a
was examined retaining The
of temper-
(a’C,,/ae~,)
values in Fig. 2. of the
their values while
numbers
examined
parameters
ez,) on the term A (T)
by changing
the other
values
values
are com-
as in the table.
were
= 6-O X 10” dynes/cm*
results
12.0 X
10’” dynes/cm2 ef,) = 1-O X 10” dynes/cm*
over
most
linear
and
2.0 x
with
numerical
values
of A (7)
case calculated
as a comparison.
the
as a function
initial
required
contribution
of
A(T)
lattice
tion
(22).
the
The
from
(8’C,,/a
upon in Fig.
Fig.
of
likely,
d-
representa-
shown
in Fig. 3
(a’C,,/ae:,)
that
the latter
The
The
precise
values
two experimental
highest
estimate
from
in
indicate
7 and 10 x our simple
of 9 X lOI dynes/cm*. deduced
to
of these points
temperature
lies between compared to
as has been
at a
depen-
experimental
sufficiently
correct
and
the magnitude
upon
former.
us to choose
theoretical
with
while it is strongly
2 are not
2 at the
a good data.
of A(T)
values
the
in Fig. 2 and
the first term of Equa-
is only weakly dependent
data
that
between
varying
e:,) demonstrate
dent
is
The
the sum of the two terms
calculations varying
and
500°K.
difference shown
shown in Fig. 2 is quite tion of the experimental with
range
above
points
In fact
that
to C&, is positive
contribution
obtained
of
1 show
is approximately
to explain
the experimental spacing
calculation
in Fig.
temperature
that (a’C,,/aef,) lOI dynes/cm’
of temperature for these parameters are shown in Fig. 3 which also includes the first
A (T) to C,i
of the temperature
magnitude
allow
10” dynes/cm2 The
of
the anharmonic
parameters. (a ‘G/a
contribution
A(T) which are shown
given temperature and
“K
4. DISCUSSION
The
the The
Temperature,
analysis
It is of
specific heat data[l9], that Cs, is sensitive to the layer stacking order. The experimental
540
B. T. KELLY
Lattice + AnharmonIc contribution
Lattice
I
I
IO00
2000 Temperature,
OK
Fig. 2. Calculated and experimental
case 1 2 3 4 5
Symbol(aC33/&) v 0
l 0 +
points
denoted
by the solid inverted
Case 5 Case 4
1.44x10'2 I.00 2.00 1.00 2.00
Temperature,
Fig. 3. Variation of anharmonic
values of C&.
(a2C44/ae&)
9.07x10'= 6.00 6Go 12.00 12.00
contribution
contribution
triangles
OK A (T) to CSSwith (62C,3/Se2z7).
in Fig. 2 correspond to a less well stacked material (P = 0.2)so that the differences may
cally two-dimensional with frequencies very strongly dependent upon the bond bending coefficient S and to an insignificant extent on
well be real (although
CSs and C,.
Ross [9] comments
that
his point at 300°K is not reliable). It must be noted that we have neglected any contribution to CSs due to the out-ofplane optical modes. previous publications,
As we have described in these modes are practi-
very
The
insensitive
bond bending to e,, and thus
coefficient is the approxi-
mation is likely to be a good one. The large magnitude of the anharmonic contribution A (T) at high temperatures has consequences for other studies which have
GRAPHITE
previously
relied
on the first term
CRYSTAL
on calculations in Equation
AS A FUNCTION
of CS5 based (22) alone.
OF TEMPERATURE
.i41
REFERENCES
1. Soule D. E. and Nezbeda C. W., J. A$$. Phys. 39, 5122 (1968). 1. It has been shown [17] that a calculation 2. Blakslee 0. Z., Proctor D. G., Seldin E. J., of (Y, as a function of temperature in which Spence G. B. and Weng T., .J. A@l. Phys. 41, CJ, and (aC,,/ae,,) are allowed to vary with 3373 (1970). the interlayer spacing alone, and not includPhys. 3. Seldin E. J. and Nezbeda C. W., J. A@/. 41, 3389 (1970). ing an anharmonic contribution, leads to seri4. Roy A. P., Can. J. Phys. 49, 277 (1970). ous disagreement with experiment at high 5. Brockhouse B. N. and Shirane G.. Bull. Amer. temperature (> 500°K). The experimental Phys. Sot. 17, 123 (1972). data and the calculations presented here for 6. Dolling G. and Brockhouse B. N., Phys. Rev. CS3 show that it varies much less than the 128, 1120 (1962). B. and Smith H., if the variation of 7. Nicklow R., Wakahabayashi lattice term alone; Phys. Rev. B5, 4951 (1972). (aC,,/a e,,) is also much less then expected 8. Ross D. K., Sanalan Y. and Szabo F. P., Therfrom the lattice term alone, due to an anharmal Neutralisation and Reactor Spectra Vol. 1, p. manic contribution, then the behaviour of (Y, 343. IAEA Vienna (1968). can be understood. 9. Ross D. K., J. Phys. C. Solid State Physics 6, 3235 2. Weertman et al. [16] have proposed a (1973). 10. Girifalco L. A. and Lad R. A., J. Chem. Phys. 25, theory of the thermal creep of polycrystalline 693 (1956). graphite in which it is necessary to estimate 11. Agranovich V. M. and Semenov L. P., J. NW/. CaJ and C44 at 2773°K and also dfi/dT the Energy 18, 141 (1961). variation of an average elastic constant p with 12. Kelly B. T. and Duff M. J., Carbon 8, 77 (1970). 13. Green J. F. and Spain I. L., To be published. temperature. These parameters were esti14. Spain I. L., Presented at the Eleventh Biennial mated from their room temperature values Carbon Conference. Gatlinbere USA (19731. and the variation with interlayer spacing as ,r Kelly B. T: and Walker P. “L., Carbon 8: 211 predicted by the Crowell me;hod.-TheexI” (1970). perimental data and the calculations pre16. Weertman J., Green W. V. and Zukas E. G., Mater. Sci. Engng 6, 199 (1970). sented here show that the use of the Crowell 17. Kelly B. T., High Temperature-High Pressure 5, method overestimates the changes considera133 (1973). bly, so that and the theory of creep needs 18 Mott N. F. and Jones H., The Theory of the re-examination. Properties of Metals and Alloys. Oxford UniverThe theory presented in this paper can sities Press (1936). 19. Komatsu K., J. Phys. Sot. Jafian 10, 346 (1955); only be tested in detail when direct measureJ. Phys. Chem. Solids 6, 380 (1958); J. Phys. Chem. ments of CS5 vs temperature become Solids 25, 707 (1963). available. 20. Kelly B. T., Carbon 11, 379 (1973). 21. Green J. F., Bolsaitis P. and Spain I. L., J. Phys. Chem. Solids 34, 1927 (1973). Acknowledgements-I am deeply indebted to Mr M. 22. Santos E. and Villagra A., Ph,ys. Rev. B6 3134 (1972). Toes of the Central Technical Services of the UKAEA for the programming of the numerical 23. Crowell D. J., Chem. Phys. 16, 1407 (1957). calculations. The UKAEA Member for Reactors, 24. Reynolds W. N., Physical Properties of Graphite. Mr R. V. Moore gave permission for this work to Elsevier Press (1968). be published. 25. Bonjour E., Private Communication.
Springfields Works, Salwick, Nr Preston, Lancashire, England
(Received
1973)
5 November
Abstract-A calculation is presented of the elastic constant CM of a graphite crystal as a function of temperature up to 2500 K, taking into account the anharmonic contribution and the changes in interlayer interactions due to the large lattice thermal expansion. Parametric variations in the theory show that the anharmonic contribution to G depends principally on the parameter (a’C,,/~e~,). Comparison of theoretical results with the experimental data, which is mainly from neutron scattering experiments, shows that the data can be accounted for if (a*CJae~,) lies in the range 7-10 X 10” dynes/cm*. A theoretical estimate of (a’C,,/ae?,) based on Lennard-Jones potentials between atoms in adjacent basal planes gives a value of 9.07 X lOI dynes/cm?. 1. INTRODUCTION Measurements highly
of the
oriented
natural
which
by
Shirane[5]
theoretical
up
variation
of the
if we know e,, as a function
variation
inter-
of C& as a function A
number
of the interlayer published[lO-131
forces and
has been
shown [12, 131 that pair potentials
vided
of
value
of C,,[12,
that
of in
tuted
it
can be used to calculate
the
of temperature,
in
anharmonic
of
effects
in
these
are small. If the values of Cs, and obtained in this way are substithe
thermal
Kelly and Walker
expansion
500°K [17]. The
theory
of
[ 151, much too large a varia-
tion of cr, with temperature neutron
is obtained scattering
above
data [4-91
indicate that Css does not decrease as rapidly with increasing temperature as the simple
first derivative with respect to strain e,, parallel to the hexagonal axis. These potentials the
ac-
of C& and (a C,,/a eLZ)with strain e,,;
parameters (aC,,/ae,,)
the Lennard-Jones and Buckingham types readily account for the value of CJJ and its
for
to
be accurately
then CQ3 and (aC,,/ae,,) can also be estimated as a function of temperature, [16, 171, pro-
and
have been
2200°K.
potentials[lO-131
of neutron
have
account
could
showed
(Y, parallel
counted for using the theoretical values of CQJ and (G,/ae,,) at 0°K. The interlayer
ap-
graphite
cannot
axis
zero.
Brockhouse
been
hexagonal
meas-
Roy [4],
to
the
coefficient
at absolute
studies
studies
values
paper [ 151 the author
the expansion
to be any direct
and others[6-91
temperature
that
tempera-
However
to yield values
In a previous
and
to be good
of the temperature
constants.
scattering preted
at ambient
to the values
and
Seldin good
and suggestions have recently been made that C4 is largely electronic in origin [14].
of
graphite
produced
constants
do not appear
urements elastic
have
constants
of Some,
are also believed
proximations There
crystals
[l-3]
for the elastic ture
pyrolytic
graphite
co-workers
elastic
131
theory of the change of interlayer forces with strain indicates, and thus either the constants
.535
536
B. T. KELLY
in the pair potentials are actually temperature dependent or the anharmonic contribution to Css is significant. There may also be anharmonic effects in (aC,,/ae,,), but the only experimental data is at ambient temperature. The purpose of this paper is to calculate the variation of Css with temperature, including both the effect of strain on the interlayer forces and the anharmonic contribution.
and, therefore,
from (3) (5)
Substituting Equation spectively gives
(1) in (3) and (5) re-
4. THEORY Consider a unit cube of graphite crystal with the c-axis parallel to a cube edge which is also the z-axis of a Cartesian coordinate system. The free energy/unit volume of the cube is written as [18]: F = E + kTx
i
In (1 - exp [- hu, /kT]),
(1)
where E k h vi
is the lattice energy/unit volume is Boltzmann’s constant, is Planck’s constant, is the i’th lattice vibrational frequency. The summation is to be taken over all lattice vibrational modes in unit volume. The thermodynamic relation between pressure P and free energy F is p=_
( > _g
*
(2)
T
The volumetric strain of a graphite crystal is essentially the same as the interlayer strain e PI, so that to a good approximation, P is equivalent to a stress a,, parallel to the hexagonal axis, i.e., (3) By definition, (4)
and
exp (-h/kT) [l - exp (-hvi/kT)]*
’
(7)
In order to evaluate Equations (7), we need the values of the lattice frequencies pi and their first and second derivatives with respect to stram eZZ. The acoustic mode lattice vibration frequencies are given in the Komatsu [19] semicontinuum model of the lattice dynamics of graphite by analytic expressions. The theory of the thermal expansion coefficients of graphite crystals developed by Kelly and Walker[15] and refined by Kelly[ZO] shows that only one vibration mode, the out-ofplane acoustic mode, is significantly modified by strain eZZ_The dispersion relation of the mode is:-
where p is the density, CT~and a, are the wave number components parallel and perpendicular to the basal planes, and 6 is the bond bending coefficient as defined by Komatsu [19]. The differentials of the dispersion relation (8) are:
GRAPHITE
The
calculations
cient
CRYSTAL
of thermal
(Y, [20] indicate
AS A FUNCTION
expansion
that (&Y/ae,,)
tively small effect compared
method
coeffi-
has a rela-
to (8 G/a
ezL_)and
537
OF TEMPERATURE
due to Crowe11[23]
riate
pair potentials
tion
over
in which approp-
are summed
a uniform
atomic
(a&/de,,). The parameter S is a property of the intra-layer covalent bonds which cannot
layer. We assume
a Lennard-Jones
be much
tween
in adjacent
thus
affected
we assume
lected
that
e%,). With
strain
(a’s/ae?,)
by comparison
(a%,,/8 tions
by interlayer with
these
e,, and
assumptions
(9) and (10) reduce
rated
may be neg-
(a’C,,/ae%)
atoms
by a distance
by integra-
density
in each
potential
layers
only,
besepa-
r
and Equa-
(13)
to:
I
+$’ P
a (12)
The values of (aC,,/ae,,) and (aC,,/ae,,) are known from the work of Spain et al. [21] but it
is a constant.
is necessary
over a uniform
mate at the
in order
(a*E/de:,),
to evaluate
(d’C,,/de:,),
interlayer
spacing
(7), to esti-
and (a’C,,/aeZ,) corresponding
to
where
plane
from
Thomas-Fermi to provide
calculations
estimates,
[22].
If Equation
following
energy/unit
0°K. Each of the above values may be estimated from atomic pair potentials between atoms in different layer planes[lO-131 or order
A is the Van Der Waals constant density
(T of atoms
Crowe11[23],
volume
and rll
(13) is integrated the
in a basal interlayer
is
E =v[;
(2)“-
11,
(14)
In
we will follow the
where
No is the number
of atoms/unit
volume
538
B. T. KELLY
and d the interlayer spacing. The equilibrium condition for the crystal at O”K, with interlayer spacing d = do, is C3E
(ad>d=4=0)
(15)
and by using d, = 3.3535 x lo-@ cm C&d,) = 3.67 X 10” dynes/cm*. In the same way we obtain
and
($?)d_d..
(20)
= d,“(j$)d;d”
= -l%s(do),
which yields r,,== 2d:.
(16)
The energy E at a spacing d different is readily found to be
from do (%)d=do
E(d) =+GV#$-+I. The elastic constant given by
1d4
($=d’(s) =!+_)[1~(!%)6_5](~)Y
(19)
The value of Equation (19) at a temperature T”K is obtained by substituting the value of d for natural graphite at that temperature [24],
0 exp {(h/k~)(4~~3*~,4 1- exp {- (h/k~)(4T’~‘u,4
((
= 251Css(d,).
-1,4d,
+ (C,,/pm2d,2) sin’ 7rd,uZ + (C~lp)c~?“*} + (Css/p,r*d2) sin’ rdOgz + (C+JP)~~)~‘~I I
C44 CQ3 sin’ rr d,u, + a,’ 47r262u,4 + 2 pn d, P C44 sin’ r d,c+, + - ua2 P (I-
exp {-- (hlkT)(4r 26 ‘aa4 + (Css/p,r2d02)sin2 Td,u, f (Cti/P)Ua’)“‘} exp {- (h/kT)(4,r*62u2+ (CQS/pr2d:) sin’ Ird,uZ + (cdPb~)“2))*
x 1 [(sin’ ~d,a,lp~*d,‘)(aCQQ/aell) + (~~21~)(acdae=)12 4 [4T262~,4 + (Css/pr2d,*) sin’ rrd,u, + G/P)u~I
which is our principal
result.
(21)
Experimentally [21] (a CM/ae,,) = - 6C44 but it is not possible to estimate (aC,/ae,,) or (d*CJae%) from the Crowell model because the assumption of a uniform atomic density in the basal planes reduces the shear resistance, and hence CM, to zero. However we note that the numerical coefficient of CSs in the equation for (#C,,/aeL) is roughly the square of the numerical coefficient of C& in the equation for (aC,,/?Je,,) and, making the same assumption for the parameters associated with shear, choose (L!‘C,,/deE,) = 35& for initial calculations. The final equation for CSs on conversion of the second term of Equation (7) from a summation to an integration over the first Brillouin zone is
0 (W
= = 12V;:No.
The first term in Equation (7) at a spacing d different from d, corresponding to temperature T”K is
’
= d,‘(j$)d_dQ
(17)
C&3at 0°K (i.e. d = d, is
C&d,) = d,2 $j [
which is to be compared with the experimental value[21] of - 15Css, and
da, I)
. due.
GRAPHITE 3. NUMERICAL
Equation
AS A FUNCTION
CRYSTAL
OF TEMPERATURE
EVALUATION
(22) is of the form
(23) where we refer to A(T) as the anharmonic contribution. The expression for A(T) in Equation tion
(23) was programmed
on a computer
Central
Technical
using
the following
by Mr
for
evalua-
M. Toes
Services
of the
numerical
of the UKAEA
values.
Numerical value
Parameter
6.623 x 10mz7 Ergs/set 2.46 X IO7 cm-’ 3.3535 X lo-” cm 2.26 gmicc 1.380 x 10-‘h Ergs/deg 6.11 X lo-” cm2/se6’ 3.67 X 10” dynes/cm’ 4.00 x 10” dynes/cm’ - 15G5 = - 5.5 x 10” dynes/cm’ - 6Cs4 = - 2.4 X 10” dynes/cm* 251C,, = 9.0’7 X 10’” dynes/cm’ 36C,, = 1.44 X 10” dynes/cm*
h (T,,,
d,,
P k
6
G C14 (aCk/de,,) (aG/de,J (dYk/deb)
(a2C.dae~,)
Fig. 1. Anharmonic
ature
value of
A (T) as a function
is shown in Fig. 1. The calculated
of Cs, as a function pared
of temperature
with the experimental
The (a’C,Ja
effect
of variation
e:,) and (a’C,,/a
was examined retaining The
of temper-
(a’C,,/ae~,)
values in Fig. 2. of the
their values while
numbers
examined
parameters
ez,) on the term A (T)
by changing
the other
values
values
are com-
as in the table.
were
= 6-O X 10” dynes/cm*
results
12.0 X
10’” dynes/cm2 ef,) = 1-O X 10” dynes/cm*
over
most
linear
and
2.0 x
with
numerical
values
of A (7)
case calculated
as a comparison.
the
as a function
initial
required
contribution
of
A(T)
lattice
tion
(22).
the
The
from
(8’C,,/a
upon in Fig.
Fig.
of
likely,
d-
representa-
shown
in Fig. 3
(a’C,,/ae:,)
that
the latter
The
The
precise
values
two experimental
highest
estimate
from
in
indicate
7 and 10 x our simple
of 9 X lOI dynes/cm*. deduced
to
of these points
temperature
lies between compared to
as has been
at a
depen-
experimental
sufficiently
correct
and
the magnitude
upon
former.
us to choose
theoretical
with
while it is strongly
2 are not
2 at the
a good data.
of A(T)
values
the
in Fig. 2 and
the first term of Equa-
is only weakly dependent
data
that
between
varying
e:,) demonstrate
dent
is
The
the sum of the two terms
calculations varying
and
500°K.
difference shown
shown in Fig. 2 is quite tion of the experimental with
range
above
points
In fact
that
to C&, is positive
contribution
obtained
of
1 show
is approximately
to explain
the experimental spacing
calculation
in Fig.
temperature
that (a’C,,/aef,) lOI dynes/cm’
of temperature for these parameters are shown in Fig. 3 which also includes the first
A (T) to C,i
of the temperature
magnitude
allow
10” dynes/cm2 The
of
the anharmonic
parameters. (a ‘G/a
contribution
A(T) which are shown
given temperature and
“K
4. DISCUSSION
The
the The
Temperature,
analysis
It is of
specific heat data[l9], that Cs, is sensitive to the layer stacking order. The experimental
540
B. T. KELLY
Lattice + AnharmonIc contribution
Lattice
I
I
IO00
2000 Temperature,
OK
Fig. 2. Calculated and experimental
case 1 2 3 4 5
Symbol(aC33/&) v 0
l 0 +
points
denoted
by the solid inverted
Case 5 Case 4
1.44x10'2 I.00 2.00 1.00 2.00
Temperature,
Fig. 3. Variation of anharmonic
values of C&.
(a2C44/ae&)
9.07x10'= 6.00 6Go 12.00 12.00
contribution
contribution
triangles
OK A (T) to CSSwith (62C,3/Se2z7).
in Fig. 2 correspond to a less well stacked material (P = 0.2)so that the differences may
cally two-dimensional with frequencies very strongly dependent upon the bond bending coefficient S and to an insignificant extent on
well be real (although
CSs and C,.
Ross [9] comments
that
his point at 300°K is not reliable). It must be noted that we have neglected any contribution to CSs due to the out-ofplane optical modes. previous publications,
As we have described in these modes are practi-
very
The
insensitive
bond bending to e,, and thus
coefficient is the approxi-
mation is likely to be a good one. The large magnitude of the anharmonic contribution A (T) at high temperatures has consequences for other studies which have
GRAPHITE
previously
relied
on the first term
CRYSTAL
on calculations in Equation
AS A FUNCTION
of CS5 based (22) alone.
OF TEMPERATURE
.i41
REFERENCES
1. Soule D. E. and Nezbeda C. W., J. A$$. Phys. 39, 5122 (1968). 1. It has been shown [17] that a calculation 2. Blakslee 0. Z., Proctor D. G., Seldin E. J., of (Y, as a function of temperature in which Spence G. B. and Weng T., .J. A@l. Phys. 41, CJ, and (aC,,/ae,,) are allowed to vary with 3373 (1970). the interlayer spacing alone, and not includPhys. 3. Seldin E. J. and Nezbeda C. W., J. A@/. 41, 3389 (1970). ing an anharmonic contribution, leads to seri4. Roy A. P., Can. J. Phys. 49, 277 (1970). ous disagreement with experiment at high 5. Brockhouse B. N. and Shirane G.. Bull. Amer. temperature (> 500°K). The experimental Phys. Sot. 17, 123 (1972). data and the calculations presented here for 6. Dolling G. and Brockhouse B. N., Phys. Rev. CS3 show that it varies much less than the 128, 1120 (1962). B. and Smith H., if the variation of 7. Nicklow R., Wakahabayashi lattice term alone; Phys. Rev. B5, 4951 (1972). (aC,,/a e,,) is also much less then expected 8. Ross D. K., Sanalan Y. and Szabo F. P., Therfrom the lattice term alone, due to an anharmal Neutralisation and Reactor Spectra Vol. 1, p. manic contribution, then the behaviour of (Y, 343. IAEA Vienna (1968). can be understood. 9. Ross D. K., J. Phys. C. Solid State Physics 6, 3235 2. Weertman et al. [16] have proposed a (1973). 10. Girifalco L. A. and Lad R. A., J. Chem. Phys. 25, theory of the thermal creep of polycrystalline 693 (1956). graphite in which it is necessary to estimate 11. Agranovich V. M. and Semenov L. P., J. NW/. CaJ and C44 at 2773°K and also dfi/dT the Energy 18, 141 (1961). variation of an average elastic constant p with 12. Kelly B. T. and Duff M. J., Carbon 8, 77 (1970). 13. Green J. F. and Spain I. L., To be published. temperature. These parameters were esti14. Spain I. L., Presented at the Eleventh Biennial mated from their room temperature values Carbon Conference. Gatlinbere USA (19731. and the variation with interlayer spacing as ,r Kelly B. T: and Walker P. “L., Carbon 8: 211 predicted by the Crowell me;hod.-TheexI” (1970). perimental data and the calculations pre16. Weertman J., Green W. V. and Zukas E. G., Mater. Sci. Engng 6, 199 (1970). sented here show that the use of the Crowell 17. Kelly B. T., High Temperature-High Pressure 5, method overestimates the changes considera133 (1973). bly, so that and the theory of creep needs 18 Mott N. F. and Jones H., The Theory of the re-examination. Properties of Metals and Alloys. Oxford UniverThe theory presented in this paper can sities Press (1936). 19. Komatsu K., J. Phys. Sot. Jafian 10, 346 (1955); only be tested in detail when direct measureJ. Phys. Chem. Solids 6, 380 (1958); J. Phys. Chem. ments of CS5 vs temperature become Solids 25, 707 (1963). available. 20. Kelly B. T., Carbon 11, 379 (1973). 21. Green J. F., Bolsaitis P. and Spain I. L., J. Phys. Chem. Solids 34, 1927 (1973). Acknowledgements-I am deeply indebted to Mr M. 22. Santos E. and Villagra A., Ph,ys. Rev. B6 3134 (1972). Toes of the Central Technical Services of the UKAEA for the programming of the numerical 23. Crowell D. J., Chem. Phys. 16, 1407 (1957). calculations. The UKAEA Member for Reactors, 24. Reynolds W. N., Physical Properties of Graphite. Mr R. V. Moore gave permission for this work to Elsevier Press (1968). be published. 25. Bonjour E., Private Communication.