Physical Foundations of Cosmology

310 Gravitational instability in General Relativity

universe with perfect fluidδT
i
j(T)=^0 ,(7.43) simplifies to
(
h′′ij+ 2 Hh′ij−hij

)

= 0. (7.95)

Introducing the rescaled variablevvia

hij=

v

a

eij, (7.96)

whereeijis a time-independent polarization tensor, and considering a plane wave
perturbation with the wavenumberk,(7.95) becomes

v′′+

(

k^2 −

a′′

a

)

v= 0. (7.97)

In aradiation-dominateduniversea∝η,hencea′′=0 andv∝exp(±ikη).In
this case the exact solution of (7.95) is

hij=

1

η

(C 1 sin(kη)+C 2 cos(kη))eij. (7.98)

The nondecaying mode of the gravitational wave with wavelength larger than the
Hubble scale(kη 1 )is constant. After the wavelength becomes smaller than
the Hubble radius, the amplitude decays in inverse proportion to the scale factor.
This is a general result valid for any equation of state.In fact, for long-wavelength
perturbations withkη 1 ,we can neglect thek^2 term in (7.97) and its solution
becomes

vC 1 a+C 2 a

∫

dη

a^2

. (7.99)

Hence,

hij=

(

C 1 +C 2

∫

dη

a^2

)

eij. (7.100)

Forp<εthe second term describes the decaying mode.
For short-wavelength perturbations(kη 1 ),we havek^2 a′′/a andh∝
exp(±ikη)/a.

Problem 7.15Find the exact solution of (7.95) for an arbitrary constant equa-
tion of statep=wεand analyze the behavior of the short- and long-wavelengh
gravitational waves. Consider separately the casesp=±ε.

7.4 Baryon–radiation plasma and cold dark matter

Understanding the perturbations in a multi-component medium consisting of a mix-
ture of a baryon–radiation plasma and cold dark matter is important both to analyze