Evolution of Vacuum Fluctuations of an Ultra-Light Massive Scalar Field generated during and before Inflation

Abstract

We consider an ultra-light scalar field with a mass comparable to (or lighter than) the Hubble parameter of the present universe, and calculate the time evolution of the energy-momentum tensor of the vacuum fluctuations generated during and before inflation until the late-time radiation-dominated and matter-dominated universe. The equation of state changes from w=1/3 in the early universe to w=-1 at present, and it can give a candidate for the dark energy that we observe today. It then oscillates between w=-1 and 1 with the amplitude of the energy density decaying as a-3. If the fluctuations are generated during ordinary inflation with the Hubble parameter HI 10-5 M Pl, where M Pl is the reduced Planck scale, we need a very large e-folding number N 1012 to explain the present dark energy of the order of 10-3 eV. If a Planckian universe with a large Hubble parameter HP M Pl existed before the ordinary inflation, an e-folding number N 240 of the Planckian inflation is sufficient.