208 12 Integral Formulae and Distribution Functions
and similarly, from (12.10) follows
FμνFλκFστFαβ〈φμνφλκφστφαβ〉 0 =
15
7
(FμνFμν)^2.
Thus up to terms of fourth order in the field tensor, the partition functionZis
Z=( 4 π)−^1
(
1 +
1
2
β 22 FμνFμν+
1
27
√
30 β^32 FμνFνκFκμ+
5
56
β 24 (FμνFμν)^2 +...
)
.
(12.31)
ForHgivenby(12.30), the equilibrium averageaμν=〈φμν〉can also be evaluated
according to
aμν=β− 21 Z−^1
∂Z
∂Fμν
=β− 21
∂lnZ
∂Fμν
. (12.32)
With the help of (11.59) andφμνλκ=^34
√
70 uμuνuλuκ, the second order term in
the expression forfeqis rewritten as
FμνFλκφμνφλκ=
15
2
FμνFλκ
(
3
4
√
70
)− 1
φμνλκ+
4
7
√
15
2
FμλFλνφμν+FμνFμν.
Thus in high temperature approximation, up to second order inβ 2 , the second and
fourth rank alignment tensors are given by
aμν=β 2 Fμν+
1
7
√
30 β 22 FμλFλν, aμνλκ=
1
2
√
10
7
β 22 FμνFλκ. (12.33)
A relation similar to (12.24) links the fourth rank alignment tensor with the product
of two second rank alignment tensors, viz.aμνλκ∼aμνaλκ and
〈uμuνuλuκ〉=c(^4 |^22 )〈uμuν〉〈uλuκ〉. (12.34)
The coefficientc(^4 |^22 )depends on the field strength. The high temperature approxi-
mation isc(^4 |^22 )= 5 /7.
12.2.5 Kerr Effect, Cotton-Mouton Effect, Non-linear
Susceptibility
The birefringence induced by an applied electric field or by a magnetic field are
calledKerr effect, named after J. Kerr, andCotton-Mouton effect, named after A.
Cotton and H. Mouton, who discovered these effects in 1875 and 1907, respectively.