Generation of intense circularly polarized attosecond light bursts from relativistic laser plasmas

Abstract

We have investigated the polarization of attosecond light bursts generated by nanobunches of electrons from relativistic few-cycle laser pulse interaction with the surface of overdense plasmas. Particle-in-cell simulation shows that the polarization state of the generated attosecond burst depends on the incident-pulse polarization, duration, carrier envelope phase, as well as the plasma scale length. Through laser and plasma parameter control, without compromise of generation efficiency, a linearly polarized laser pulse with azimuth θi=10 can generate an elliptically polarized attosecond burst with azimuth |θr atto|≈61 and ellipticity σr atto≈0.27; while an elliptically polarized laser pulse with σi≈0.36 can generate an almost circularly polarized attosecond burst with σr atto≈0.95. The results propose a new way to a table-top circularly polarized XUV source as a probe with attosecond scale time resolution for many advanced applications.