Vector induced Gravitational Waves sourced by Primordial Magnetic Fields

Abstract

In this work, we develop a generic formalism for the study of tensor perturbations induced at second order by first-order vector metric perturbations, dubbing these induced tensor modes vector-induced gravitational waves (VIGWs). Notably, considering an inflation-inspired power-law type magnetic field power spectrum of the form PB(k) knB (where n B is the magnetic spectral index), we show that the VIGW signal is enhanced for stiff post-inflationary EoS, with the maximum enhancement happening for w=1. We explicitly demonstrate this contribution is dominant over the first-order magnetically-sourced GWs. The VIGW spectrum exhibits a maximum at around the scale crossing the cosmological horizon at the end of reheating, kreh, with its present day peak amplitude scaling as GW(k reh,η0) N reh×(H inf/M Pl)8, where H inf is the Hubble parameter at the end of inflation and N reh the duration of the post-inflationary era in e-folds. For w=1 (kination) and n B>-3/2, one further obtains a nearly n B-independent frequency scaling of the GW spectrum of the form GW(f,η0) (ff reh)-2.8 for f>freh kreh/(2π). Finally, we highlight that the VIGW signal can be well within the detection bands of several next-generation interferometric GW missions at small scales. Indicatively, for H inf O(107)\:GeV and O(1014)\:GeV, and N reh 15 and 10, the VIGW signal is expected to be detectable by LISA and ET respectively.

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