Stringent requirements for detecting light-induced gravitational effects using interferometry
Abstract
Intense laser fields have been proposed as a means to generate light-induced gravitational effects, providing a novel approach to investigate gravity and its coupling to electromagnetism in a controlled laboratory setting. In this article, a detection scheme based on interferometry is introduced to assess the feasibility of observing such effects. Initially, the space-time deformation and the resulting induced phase difference are evaluated in homogeneous electric fields. Using the theoretical minimum phase sensitivity bound -- a known result in quantum information -- and accounting for background signal coming from photon-photon scattering -- a fundamental quantum electrodynamics effect related to vacuum properties -- a set of stringent requirements for detectability is obtained. Then, a more realistic scenario is considered where gravitational effects are generated by an e-dipole pulse. In all cases considered, it is demonstrated that observing these effects presents significant challenges, even with the capabilities of current and foreseen laser infrastructures.
Cite
@article{arxiv.2506.05534,
title = {Stringent requirements for detecting light-induced gravitational effects using interferometry},
author = {F. Fillion-Gourdeau and S. MacLean},
journal= {arXiv preprint arXiv:2506.05534},
year = {2025}
}
Comments
14 pages, 2 figures