166 The very early universe
following equation for ̄χ(t):
χ ̄;α;α+V′(χ ̄)+1
2
V′′′(χ ̄)〈
φ^2〉
= 0 , (4.94)
where the higher-order terms∼
〈
φ^3〉
,etc. have been neglected. In quantum field
theory this corresponds to the so called one-loop approximation. We will now show
that in a hot universe the last term in (4.94) can be combined withV′(χ ̄)and
rewritten as the derivative of an effective potentialVeff(χ, ̄ T).To this purpose, let
us calculate the average
〈
φ^2〉
.
Scalar field quantizationIn the lowest (linear) order, the inhomogeneous modesφ
obey the equation
φ;α;α+V′′(χ ̄)φ= 0 , (4.95)obtained by linearizing (4.92). Assuming that the mass
m^2 φ(χ ̄)≡V′′(χ ̄)≥ 0does not depend on time, and neglecting the expansion of the universe (this is a
good approximation for our purposes), the solution of (4.95) is
φ(x,t)=∫
1
√
2 ωk(
e−iωkt+ikxa−k+eiωkt−ikxak+) d^3 k
( 2 π)^3 /^2, (4.96)
where
ωk=√
k^2 +V′′(χ ̄)=√
k^2 +m^2 φ,k≡|k|,andak−,a+k =
(
ak−)∗
are the integration constants. Our task is to calculate
both quantum and thermal contributions to
〈
φ^2〉
.
In quantum theory, the fieldφ(x,t)≡φx(t)becomes a “position” operatorφˆx(t)
and the spatial coordinatesxcan be considered simply as enumerating the degrees of
freedom of the physical system. That is, at each point in space, we have one degree of
freedom – a field strength – which plays the role of position in a configuration space.
Hence, a quantum field is a quantum mechanical system with an infinite number of
degrees of freedom. As in usual quantum mechanics, the position operatorsφˆx(t)
and their conjugated momenta
πˆy≡∂L/∂φ ̇=∂φˆy/∂tshould satisfy the Heisenberg commutation relations:
[
φˆx(t),πˆy(t)]
=
[
φˆx(t),∂φˆy(t)
∂t]
=iδ(x−y), (4.97)