Robertson-Walker Metrics

We now study simple models of the universe, and therefore assume both homogeneity and isotropy. As discussed in §Cosmological Principle, homogeneity implies that spacetime is foliated by spacelike hypersurfaces $\Sigma_t$; isotropy implies there are preferred “cosmic observers” orthogonal to these hypersurfaces. Thus, each $\Sigma_t$ represents an instant of time according to these cosmic observers. We can therefore assume without loss of generality that the surfaces are labeled using “cosmic time”, that is, that $t$ is proper time according to these cosmic observers.

The line element therefore takes the form \begin{equation} ds^2 = -dt^2 + h_{ij}\,dx^i\,dx^j \label{metrichi} \end{equation} where $h_{ij}$ are the components of the line element restricted to $\Sigma_t$. There are no cross terms in ($\ref{metrichi}$), since the worldlines of cosmic observers are orthogonal to $\Sigma_t$.

Figure 1: An expanding spherical balloon, shown at 3 different instants of time.

Homogeneity implies that each $\Sigma_t$ has no privileged points; among other things, this means that the curvature must be constant. Thus, each $\Sigma_t$ must be a surface of constant curvature, as discussed in §Constant Curvarture. The line element therefore becomes \begin{equation} ds^2 = -dt^2 + a(t)^2 \left( \frac{dr^2}{1-kr^2} + r^2 \left( d\theta^2 + \sin^2\theta\,d\phi^2 \right) \right) \end{equation} which is known as the Robertson-Walker metric. The free parameters are $k$, which determines the shape of space, and $a(t)$, which determines the scale of the universe as a function of cosmic time. You can think of the universe as the surface of a balloon, whose “radius” is given by $a(t)$, although this analogy is only strictly true for the spherical case ($k=1$), which is illustrated in Figure 1. The parameter $k$ also determines the topology of the universe; the universe is closed (finite) if $k=1$, and open (infinite) otherwise.

It is straightforward to compute the Einstein tensor for the Robertson-Walker metric. As shown in §Robertson-Walker Curvature, the independent, nonzero curvature 2-forms are \begin{align} \Omega^t{}_r &= \frac{\ddot{a}}{a}\sigma^t\wedge \sigma^r \\ \Omega^t{}_\theta &= \frac{\ddot{a}}{a}\sigma^t\wedge \sigma^\theta \\ \Omega^t{}_\phi &= \frac{\ddot{a}}{a}\sigma^t\wedge \sigma^\phi \\ \Omega^r{}_\theta &= \frac{\dot{a}^2+k}{a^2}\sigma^r\wedge\sigma^\theta \\ \Omega^r{}_\phi &= \frac{\dot{a}^2+k}{a^2}\sigma^r\wedge\sigma^\phi \\ \Omega^\theta{}_\phi &= \frac{\dot{a}^2+k}{a^2}\sigma^\theta\wedge\sigma^\phi \end{align} and the nonzero components of the Einstein tensor are \begin{align} G^t{}_t &= -3 \left( \frac{\dot{a}^2+k}{a^2} \right) \\ G^r{}_r = G^\theta{}_\theta = G^\phi{}_\phi &= - \left( \frac{2a\ddot{a}+\dot{a}^2+k}{a^2} \right) \end{align} Thus, the Einstein tensor has precisely the form of the energy-momentum tensor of a perfect fluid! This shouldn't be a surprise, since we have assumed homogeneity and isotropy. Inserting the Einstein tensor into Einstein's equation (with cosmological constant), and assuming the energy-momentum tensor is indeed a perfect fluid, we obtain \begin{align} -3 \left( \frac{\dot{a}^2+k}{a^2} \right) + \Lambda &= -8\pi\rho \\ - \left( \frac{2a\ddot{a}+\dot{a}^2+k}{a^2} \right) + \Lambda &= 8\pi p \end{align} where $\rho$ is the energy density and $p$ the pressure density, and where both of these densities are functions of time $t$.


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