The Schwinger effect by axial coupling in natural inflation model

Abstract

We investigate the process of the Schwinger effect by axial coupling in the natural single-field inflation model in two parts. First we consider the Schwinger effect when the conformal invariance of Maxwell action should be broken by axial coupling I(φ)FμFμ with the inflaton field by identifying the standard horizon scale k=aH at the very beginning of inflation for additional boundary term and use several values of coupling constant 1 and estimate electric and magnetic energy densities and energy density of produced charged particles due to the Schwinger effect.We find that for both coupling functions the energy density of the produced charged particles due to the Schwinger effect is so high and spoils inflaton field.In fact the strong coupling or back-reaction occurs because the energy density of produced charged particles is exceeding of inflaton field.We use two coupling functions to break conformal invariance of maxwell action.The simplest coupling function I(φ)=1φMp and a curvature based coupling function I(φ)= 121e(23φMp)[13Mp2(4V(φ))+23Mp(dVdφ)] where V(φ) is the potential of natural inflation. In second part , in oder to avoid strong back-reaction problem we identify the horizon scale kH=aH|ζ| , ζ=I(φ)φH in which a given Fourier begins to become tachyonically unstable.The effect of this scale is reducing the value of coupling constant 1 and weakening the back-reaction problem but in both cases strong coupling or strong back-reaction exists and the Schwinger effect is impossible.