Investigating dark energy by electromagnetic frequency shifts

TL;DR

This paper explores whether electromagnetic frequency shifts from extended electromagnetism theories can explain cosmic redshift observations without requiring dark energy or accelerated expansion.

Contribution

It introduces a novel cosmological model where electromagnetic frequency shifts from ETE theories account for redshift, challenging the need for dark energy.

Findings

Frequency shift $z_S$ can mimic accelerated expansion effects.

Data fits suggest $z_S$ supports alternative explanations to dark energy.

Laboratory tests are proposed to verify ETE-induced shifts.

Abstract

The observed red shift $z$ might be composed by the expansion red shift $z_{\rm C}$ and an additional frequency shift $z_{\rm S}$, towards the red or the blue, by considering Extended Theories of Electromagnetism (ETE). Indeed, massive photon theories - the photon has a real mass as in the de Broglie-Proca theory or an effective mass as in the Standard-Model Extension (SME), based on Lorentz-Poincar\'e Symmetry Violation (LSV) - or Non-Linear Electro-Magnetism (NLEM) theories may induce a cosmological expansion independent frequency shift in presence of background (inter-) galactic electromagnetic fields, and where of relevance LSV fields, even when both fields are constant. We have tested this prediction considering the Pantheon Catalogue, composed by 1048 SNe Ia, and 15 BAO data, for different cosmological models characterised by the absence of a cosmological constant. From the data, we compute which values of $z_{\rm S}$ match the observations, spanning cosmological parameters ($\Omega$ densities and Hubble-Lema\^itre constant) domains. We conclude that the frequency shift $z_{\rm S}$ can support an alternative to accelerated expansion, naturally accommodating each SN Ia position in the distance-modulus versus red shift diagram, due to the light-path dependency of $z_{\rm S}$. Finally, we briefly mention laboratory test approaches to investigate the additional shift from ETE predictions.