Stabilization of Starobinsky-Vilenkin stochastic inflation by an environmental noise

Abstract

We discuss the inflaton φ in an interaction with an infinite number of fields treated as an environment (noise) with a friction γ2>0. In a Markovian approximation we obtain a stochastic wave equation (appearing also in the warm inflation models). After the replacement of the environment by the white noise, the stochastic wave equation violates the energy conservation if γ≠ 0. We introduce a dark energy as a compensation of the inflaton energy-momentum. We add to the classical wave equation the Starobinsky-Vilenkin noise which in the slow-roll approximation describes the quantum fluctuations in an expanding metric. We investigate the resulting consistent Einstein-Klein-Gordon system in the slow-roll regime. We obtain Fokker-Planck equation for the probability distribution of the inflaton assuming that the dependence of the scale factor a and the Hubble variable H on the field φ is known. We obtain explicit stationary solutions of the Fokker-Planck equation assuming that a(φ) and H(φ) can approximately be determined in a slow-roll regime with the neglect of noise. We extend the results to the multifield D-dimensional configuration space. We show that in the regime a(φ)3H(φ)5→ ∞ the quantum noise determines the asymptotic behaviour of the stationary distribution. If a(φ)3H(φ)5 stays finite then the environmental noise ensures the integrability of the stationary probability. In such a case there is no need to introduce boundary conditions with the purpose to eliminate infinite inflation. The variation of a(φ)3H(φ)5 could be interpreted as a sign of a transition from cold inflation to warm inflation.