112 Microcanonical ensemble
(
x(∆t)
p(∆t))
≈exp(
∆t
2F(x(0))∂
∂p(0))
×exp(
∆t
p(0)
m∂
∂x(0))
×exp(
∆t
2F(x(0))∂
∂p(0))(
x(0)
p(0))
. (3.10.24)
In order to make the notation less cumbersome in the proceeding analysis, we will
drop the “(0)” label and write eqn. (3.10.24) as
(
x(∆t)
p(∆t))
≈exp(
∆t
2F(x)∂
∂p)
exp(
∆t
p
m∂
∂x)
exp(
∆t
2F(x)∂
∂p)(
x
p)
. (3.10.25)
The “(0)” label will be replaced at the end.
The propagation is determined by acting with each of the three operators in suc-
cession onxandp. But how do we apply exponential operators? Let us start by asking
how the operator exp(c∂/∂x), wherecis independent ofx, acts on an arbitrary func-
tiong(x). The action of the operator can be worked out by expanding the exponential
in a Taylor series
exp(
c∂
∂x)
g(x) =∑∞
k=01
k!(
c∂
∂x)k
g(x)=
∑∞
k=01
k!
ckg(k)(x), (3.10.26)whereg(k)(x) = dkg/dxk. The second line of eqn. (3.10.26) is just the Taylor expansion
ofg(x+c) aboutc= 0. Thus, we have the general result
exp(
c∂
∂x)
g(x) =g(x+c), (3.10.27)which we can use to evaluate the action of the first operator in eqn.(3.10.25):
exp(
∆t
2F(x)∂
∂p)(
x
p)
=
xp+∆ 2 tF(x)
. (3.10.28)
The second operator, which involves a derivative with respect to position, acts on the
xappearing in both components of the vector on the right side of eqn. (3.10.28):
exp(
∆t
p
m∂
∂x)
xp+∆ 2 tF(x)
=
x+ ∆tmpp+∆ 2 tF(
x+ ∆tmp