Particle production and classical condensates in de Sitter space
Abstract
The cosmological particle production in a k=0 expanding de Sitter universe with a Hubble parameter H0 is considered for various values of mass or conformal coupling of a free, scalar field. One finds that, for a minimally coupled field with mass 0 ≤ m2 < 9 H02/4 (except for m2= 2H02), the one-mode occupation number grows to unity soon after the physical wavelength of the mode becomes larger than the Hubble radius, and afterwards diverges as n(t) O(1)(λphys(t)/H0-1)2, where [9/4 - m2/H02]1/2. However, for a field with m2 > 9H02/4, the occupation number of a mode outside the Hubble radius is rapidly oscillating and bounded and does not exceed unity. These results, readily generalized for cases of a nonminimal coupling, provide a clear argument that the long-wavelength vacuum fluctuations of low-mass fields in an inflationary universe do show classical behavior, while those of heavy fields do not. The interaction or self-interaction does not appear necessary for the emergence of classical features, which are entirely due to the rapid expansion of the de Sitter background and the upside-down nature of quantum oscillators for modes outside the Hubble radius.
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