Calculating the local-type fNL for slow-roll inflation with a non-vacuum initial state

Abstract

Single-field slow-roll inflation with a non-vacuum initial state has an enhanced bispectrum in the local limit. We numerically calculate the local-type fNL signal in the CMB that would be measured for such models (including the full transfer function and 2D projection). The nature of the result depends on several parameters, including the occupation number Nk, the phase angle θk between the Bogoliubov parameters, and the slow-roll parameter ε. In the most conservative case, where one takes θk ≈ η0 k (justified by physical reasons discussed within) and ε 0.01, we find that 0 < fNL < 1.52 (ε/0.01), which is likely too small to be detected in the CMB. However, if one is willing to allow a constant value for the phase angle θk and Nk=O(1), fNL can be much larger and/or negative (depending on the choice of θk), e.g. fNL ≈ 28 (ε/0.01) or -6.4 (ε/0.01); depending on ε, these scenarios could be detected by Planck or a future satellite. While we show that these results are not actually a violation of the single-field consistency relation, they do produce a value for fNL that is considerably larger than that usually predicted from single-field inflation.