Abstract

When the gauge fields have derivative couplings to scalars, like in the case of the relativistic theory of Van der Waals (or Casimir-Polder) interactions, conformal invariance is broken but the magnetic and electric susceptibilities are not bound to coincide. We analyze the formation of large-scale magnetic fields in slow-roll inflation and find that they are generated at the level of a few hundredths of a nG and over typical length scales between few Mpc and $100$ Mpc. Using a new time parametrization that reduces to conformal time but only for coincident susceptibilities, the gauge action is quantized while the evolution equations of the corresponding mode functions are more easily solvable. The power spectra depend on the normalized rates of variation of the two susceptibilities (or of the corresponding gauge couplings) and on the absolute value of their ratio at the beginning of inflation. We pin down explicit regions in the parameter space where all the physical requirements (i.e. the backreaction constraints, the magnetogenesis bounds and the naturalness of the initial conditions of the scenario) are jointly satisfied. Weakly coupled initial data are favoured if the gauge couplings are of the same order at the end of inflation. Duality is systematically used to simplify the analysis of the wide parameter space of the model.

Highlights

  • Magnetic fields with typical correlation scales exceeding the astronomical unit permeate the interstellar and intergalactic plasmas which are, in many respects, very similar to the one we can produce in terrestrial experiments [1,2]

  • Magnetogenesis models based on derivative couplings have been comprehensively analyzed

  • A similar kind of framework arises in the relativistic generalization of Van der Waals interactions

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Summary

INTRODUCTION

Magnetic fields with typical correlation scales exceeding the astronomical unit (i.e., roughly 1013 cm) permeate the interstellar and intergalactic plasmas which are, in many respects, very similar to the one we can produce in terrestrial experiments [1,2]. The purpose of the present paper is to undertake a comprehensive analysis of the parameter space of this scenario in terms of the initial conditions and of the evolution of the gauge couplings. To achieve this goal the expressions of Mρσ and N ρσ shall be first generalized. The magnetic and electric power spectra are derived in Sec. IV; we shall analyze how the different regions of the parameter space are transformed under duality and conclude that the most relevant region (from the practical viewpoint) is represented by the first quadrant of the ðFB; FEÞ plane.

Covariant decompositions
Equations of motion and duality
Coupling functions and scalar fields
Power-law backgrounds
Slow-roll models
M 2P φ φi
Time reparametrization of the action and quantization
General solutions for the mode functions
Exact solutions with asymmetric gauge couplings
Correlation functions
General form of the power spectra
Physical regions of the parameter space
Dualizing the regions of the parameter space
CHARTING THE PARAMETER SPACE OF MAGNETOGENESIS
Backreaction constraints
Dualizing the contour plots
Magnetogenesis requirements
CONCLUDING REMARKS

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