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Polarized ultrashort brilliant multi-GeV $gamma$-rays via single-shot laser-electron interaction

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 Added by Jianxing Li
 Publication date 2019
  fields Physics
and research's language is English




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Generation of circularly-polarized (CP) and linearly-polarized (LP) $gamma$-rays via the single-shot interaction of an ultraintense laser pulse with a spin-polarized counterpropagating ultrarelativistic electron beam has been investigated in nonlinear Compton scattering in the quantum radiation-dominated regime. For the process simulation a Monte Carlo method is developed which employs the electron-spin-resolved probabilities for polarized photon emissions. We show efficient ways for the transfer of the electron polarization to the high-energy photon polarization. In particular, multi-GeV CP (LP) $gamma$-rays with polarization of up to about 95% can be generated by a longitudinally (transversely) spin-polarized electron beam, with a photon flux at a single shot meeting the requirements of recent proposals for the vacuum birefringence measurement in ultrastrong laser fields. Such high-energy, high-brilliance, high-polarization $gamma$-rays are also beneficial for other applications in high-energy physics, nuclear physics, and laboratory astrophysics.



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126 - Kun Xue , Zhen-Ke Dou , Feng Wan 2020
Generation of highly-polarized high-energy brilliant $gamma$-rays via laser-plasma interaction has been investigated in the quantum radiation-reaction regime. We employ a quantum-electrodynamics particle-in-cell code to describe spin-resolved electron dynamics semiclassically and photon emission and polarization quantum mechanically in the local constant field approximation. As an ultrastrong linearly-polarized (LP) laser pulse irradiates on a near-critical-density (NCD) plasma followed by an ultrathin planar aluminum target, the electrons in NCD plasma are first accelerated by the driving laser to ultrarelativistic energies, and then head-on collide with reflected laser pulse by the aluminum target, emitting brilliant LP $gamma$-rays due to nonlinear Compton scattering with an average polarization of about 70% and energy up to hundreds of MeV. By comparison, as a conical gold target filled with NCD plasma is employed, the linear polarization degree, collimation and brilliance of emitted $gamma$-ray beam are all significantly improved due to the enhanced strong laser-driven quasi-static magnetic field in plasmas. Such $gamma$-rays can be produced with currently achievable laser facilities and find various applications in high-energy physics and astrophysics.
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199 - W. Lu , M. Tzoufras , 2006
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