Energy Fluctuations Generated by Inflation

Abstract

The energy density correlation function C(x,y)=<(x)(y)>-<>2 and its Fourier transform generated by the gravitational tidal forces of the inflationary de Sitter expansion are derived for a massless or light (m<<H) neutral scalar field without self--interactions, minimally coupled to gravity. The field has no classical background component, <>=0. Every observationally relevant mode (which has today λphys<H0-1) had at early times R/kphys20, and is taken to be initially in the Minkowski vacuum state. Our computation of C(x,y), which involves four field operators, is finite and unambiguous at each step, since we use the following two tools: (1) We use a normal ordered energy density operator N[] and show that any normal ordering N gives the same finite result. (2) Since C(x,y) has the universal |x-y|-8 short--distance behaviour, the Fourier transform can only be performed after smearing the energy density operator in space and time with a smearing scale τ. The resulting energy density fluctuations are non--Gaussian, but obey a 2--distribution. The power spectrum involves a smearing scale τ, and we choose τ=k-1. For massless scalars we obtain k3 H4k4 on super--horizon scales k<H. For light scalars with masses m H a plateau appears on the largest scales k<m3/H, the result is k3 m6H2(k/H)4m2/3H2. On sub--horizon scales k>H we have the universal law k3 k8.

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