Approximations 561novel Monte-Carlo schemes to be devised for computing this function (Jadhao and
Makri, 2008).
The second alternate time correlation function is the Kubo-transformed correlation
function (Kuboet al., 1985) defined by
KAB(t) =1
βQ(N,V,T)∫β0dλTr[
e−(β−λ)Hˆˆ
Ae−λ
Hˆ
ei
Hˆt/ ̄hˆ
Be−i
Hˆt/ ̄h]. (14.6.11)
LikeGAB(t),KAB(t) is also purely real. In addition,KAB(t) reduces to its classical
counterpart both in the classical (β→0) and harmonic limits. Consequently,KAB(t)
can be more readily compared to corresponding classical and harmonic time correlation
functions, which can be computed straightforwardly. As withGAB(t), there is a simple
relationship between the Fourier transforms ofKAB(t) andCAB(t):
C ̃AB(ω) =[
β ̄hω
1 −e−βhω ̄]
K ̃AB(ω). (14.6.12)Finally, we note that purely imaginary time correlation functions of the formGAB(τ) =1
Q(N,V,T)
Tr[
e−βHˆ ˆ
Ae−τHˆˆ
BeτHˆ]
(14.6.13)
can be computed straightforwardly using the numerical techniques for imaginary-time
path integrals. Eqn. (14.6.13) results from eqn. (14.6.1) when the Wick rotation from
real to imaginary time is applied (see Section 12.2 and Fig. 12.5). An example of such
a correlation function is the imaginary-time mean square displacement given by
R^2 (τ) =〈|xˆ(τ)−ˆx(0)|^2 〉, (14.6.14)which forNparticles in three dimensions becomes
R^2 (τ) =1
N
∑N
i=1〈
[ˆri(τ)−ˆri(0)]^2〉
. (14.6.15)
Here,τ∈[0,β ̄h/2] (R^2 (τ) is symmetric aboutτ=β ̄h/2) and for a free particle, its
shape is anR^2 (τ)∝τ(β ̄h/ 2 −τ), where the constant of proportionality depends on
the number of dimensions (see Problem 14.11). This important quantity is related
to the real-time velocity autocorrelation functionCvv(t) (more precisely, its Fourier
transformC ̃vv(ω)) via a two-sided Laplace transform
R^2 (τ) =1
π∫∞
−∞dω
e−β ̄hω/^2
ω^2C ̃vv(ω)×
{
cosh[
ω(
̄hβ
2
−τ)]
−cosh(
β ̄hω
2)}
. (14.6.16)
Eqn. (14.6.16) suggests that performing the Wick rotation from real to imaginary
time is a well-posed problem that requires a Fourier transform followed by a Laplace