Physical Foundations of Cosmology

274 Gravitational instability in Newtonian theory

time-translational-invariant. For smallτ, the time-shifted solutionε 0 (t+τ)can be
considered as a perturbation of the backgroundε 0 (t)with amplitude

δd=

ε 0 (t+τ)−ε 0 (t)

ε 0 (t)

≈

ε ̇ 0 τ

ε 0

∝H(t).

Once we know one solution of the second order differential equation,δd, then the
other independent solutionδican easily be found with the help of the Wronskian,

W≡δ ̇dδi−δd ̇δi. (6.51)

Taking the derivative of the Wronskian and using (6.47) to expressδ ̈in terms ofδ ̇
andδ, we find thatWsatisfies the equation

W ̇ =− 2 HW, (6.52)

which has the obvious solution

W≡δ ̇dδi−δd ̇δi=

C

a^2

, (6.53)

whereCis a constant of integration. Substituting the ansatzδi=δdf(t)into (6.53),
we obtain an equation forfthat is readily integrated:

f=−C

∫

dt

a^2 δd^2

. (6.54)

Thus the most general longwave solution of (6.47) is

δ=C 1 H

∫

dt

a^2 H^2

+C 2 H. (6.55)

In a flat, matter-dominated universe,a∝t^2 /^3 andH∝t−^1 .In this case, we have

δ=C 1 t^2 /^3 +C 2 t−^1. (6.56)

Hence, we see that in an expanding universe, gravitational instability ismuch less
efficientand the perturbation amplitude increases only as a power of time. In the im-
portant case of a flat, matter-dominated universe, the growing mode is proportional
to the scale factor. Therefore, if we want to obtain large inhomogeneities

(

δ 1

)

today, we have to assume that at early times (for example, at redshiftsz=1000) the
inhomogeneities were already substantial (δ 10 −^3 ).This imposes rather strong
constraints on the initial spectrum of perturbations. We will see in Chapter 8 that
the required initial spectrum can be explained naturally in inflationary cosmology.

Problem 6.3Calculate the peculiar velocities and gravitational potential for the
long-wavelength perturbations. Analyze their behavior and give the physical inter-
pretation of the behavior of the gravitational potential for the growing mode.