Reheating constraints to inflationary models

Abstract

Evidence from the BICEP2 experiment for a significant gravitational-wave background has focussed attention on inflaton potentials V(φ) φα with α=2 ("chaotic" or "m2φ2" inflation) or with smaller values of α, as may arise in axion-monodromy models. Here we show that reheating considerations may provide additional constraints to these models. The reheating phase preceding the radiation era is modeled by an effective equation-of-state parameter w re. The canonical reheating scenario is then described by w re=0. The simplest α=2 models are consistent with w re = 0 for values of ns well within the current 1σ range. Models with α=1 or α=2/3 require a more exotic reheating phase, with -1/3<w re<0, unless ns falls above the current 1σ range. Likewise, models with α=4 require a physically implausible w re>1/3, unless ns is close to the lower limit of the 2σ range. For m2φ2 inflation and canonical reheating as a benchmark, we derive a relation 10(T re/106\, GeV ) 2000\,(ns-0.96) between the reheat temperature T re and the scalar spectral index ns. Thus, if ns is close to its central value, then T re 106~GeV, just above the electroweak scale. If the reheat temperature is higher, as many theorists may prefer, then the scalar spectral index should be closer to ns0.965 (at the pivot scale k=0.05\, Mpc-1), near the upper limit of the 1σ error range. Improved precision in the measurement of ns should allow m2φ2, axion-monodromy, and φ4 models to be distinguished, even without precise measurement of r, and to test the m2φ2 expectation of ns0.965.