Probing the radiation-dominated regime of laser-plasma interaction in multi-beam configurations of petawatt lasers

Abstract

We model numerically the ultrarelativistic dynamics of a dense plasma microtarget in a focus of several intersecting femtosecond laser pulses of multi-petawatt power each. The aim is to examine perspective future experimental approaches to the search of the Inverse Faraday Effect induced by radiation friction. We show that multi-beam configurations allow lowering the peak laser power required to generate a detectable quasi-static longitudinal magnetic field excited due to the radiation reaction force. The effect remains significant at angles around $10^{\rm o}$ between the beams, vanishes when the angle exceeds $20^{\rm o}$, and remains rather stable with respect to variations of relative phases and amplitudes of the beams. We conclude that using four infrared femtosecond linearly polarized pulses, 15 petawatt power each, crossing at angles $\approx 10^{\rm o}$, the radiation-dominated regime of laser-plasma interaction can be experimentally demonstrated.