Abstract
Axion inflation coupled to the Standard Model (SM) hypercharge gauge sector represents an attractive scenario for the generation of primordial hypermagnetic fields. The description of this scenario is, however, complicated by the Schwinger effect, which gives rise to highly nonlinear dynamics. Hypermagnetogenesis during axion inflation in the absence of nonlinear effects is well studied and known to result in a hypermagnetic energy density that scales like $H^4\,e^{2\pi\xi}/\xi^5$, where $\xi$ is proportional to the time derivative of the axion-vector coupling in units of the Hubble rate $H$. In this paper, we generalize this result to the full SM case by consistently taking into account the Schwinger pair production of all SM fermions. To this end, we employ the novel gradient-expansion formalism that we recently developed in [2109.01651], and which is based on a set of vacuum expectation values for bilinear hyperelectromagnetic functions in position space. We parametrize the numerical output of our formalism in terms of three parameters ($\xi$, $H$, and $\Delta$, where the latter accounts for the damping of subhorizon gauge-field modes because of the finite conductivity of the medium) and work out semianalytical fit functions that describe our numerical results with high accuracy. Finally, we validate our results by comparing them to existing estimates in the literature as well as to the explicit numerical results in a specific inflationary model, which leads to good overall agreement. We conclude that the systematic uncertainties in the description of hypermagnetogenesis during axion inflation, which previously spanned up to several orders of magnitude, are now reduced to typically less than 1 order of magnitude, which paves the way for further phenomenological studies.
Highlights
Baryonic matter in the Universe mostly exists in the form of plasma
Hypermagnetogenesis during axion inflation in the absence of nonlinear effects is well studied and known to result in a hypermagnetic energy density that scales like H4e2πξ=ξ5, where ξ is proportional to the time derivative of the axion-vector coupling in units of the Hubble rate H
We conclude that the systematic uncertainties in the description of hypermagnetogenesis during axion inflation, which previously spanned up to several orders of magnitude, are reduced to typically less than 1 order of magnitude, which paves the way for further phenomenological studies
Summary
Baryonic matter in the Universe mostly exists in the form of plasma. Being composed of free-streaming charged particles, plasma very efficiently screens electric fields. We will study the efficiency of gauge-field production during axion inflation in terms of a minimal number of parameters (the gaugefield production parameter ξ, Hubble rate H, and damping factor Δ; see Sec. II for the precise definition of these quantities), which will provide us with numerical results that are applicable across a large range of models based on different types of scalar potentials. [49,54] span several orders of magnitude, our new estimates are capable of reducing the uncertainty in the description of hypermagnetogenesis (without specifying a concrete model and solving the equations of the gradient-expansion formalism explicitly) down to roughly less than 1 order of magnitude This becomes apparent when comparing the explicit outcome of a specific inflationary model to three available model-independent estimates We assume that the Universe is described by a spatially flat Friedmann-Lemaître-Robertson-Walker metric in terms of cosmic time, gμν 1⁄4 diagf1; −a2ðtÞ; −a2ðtÞ; −a2ðtÞg
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