Long-Time Asymptotics of a Bohmian Scalar Quantum Field in de Sitter Space-Time

Abstract

We consider a model quantum field theory with a scalar quantum field in de Sitter space-time in a Bohmian version with a field ontology, i.e., an actual field configuration ( x,t) guided by a wave function on the space of field configurations. We analyze the asymptotics at late times (t∞) and provide reason to believe that for more or less any wave function and initial field configuration, every Fourier coefficient k(t) of the field is asymptotically of the form c k1+ k2 (-2Ht)/H2, where the limiting coefficients c k= k(∞) are independent of t and H is the Hubble constant quantifying the expansion rate of de Sitter space-time. In particular, every field mode k possesses a limit as t∞ and thus "freezes." This result is relevant to the question whether Boltzmann brains form in the late universe according to this theory, and supports that they do not.