Probing Lorentz violation effects via a laser beam interacting with a high-energy charged lepton beam

Abstract

In this work, the conversion of linear polarization of a laser beam to circular one through its forward scattering by a TeV order charged lepton beam in the presence of Lorentz violation correction is explored. We calculate the ratio of circular polarization to linear one (Faraday Conversion phase φFC) of the laser beam interacting with either electron or the muon beam in the framework of the quantum Boltzmann equation. Regarding the experimentally available sensitivity to the Faraday conversion φFC 10-3-10-2, we show that the scattering of a linearly polarized laser beam with energy k0 0.1 eV and an electron/muon beam with flux εe,μ 1010/1012 TeV cm-2 s-1 places an upper bound on the combination of lepton sector Lorentz violation coefficients cμ components (cTT+1.4~c(TZ)+0.25(cXX+cYY+2~cZZ)). The obtained bound on the combination for the electron beam is at the 4.35× 10-15 level and for the muon beam at the 3.9× 10-13 level. It should be mentioned that the laser and charged lepton beams considered here to reach the experimentally measurable φFC are currently available or will be accessible in the near future. This study provides a valuable supplementary to other theoretical and experimental frameworks for measuring and constraining Lorentz violation coefficients.