在激光与预偏振等离子体的相互作用中通过自注入产生偏振电子束

IF 5.2 1区 物理与天体物理 Q1 OPTICS
L. R. Yin, X. F. Li, Y. J. Gu, N. Cao, Q. Kong, M. Büscher, S. M. Weng, M. Chen, Z. M. Sheng
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引用次数: 0

摘要

通过粒子入胞模拟研究了在预极化等离子体中通过激光汪场加速产生的极化电子束。根据横向和纵向自注入的托马斯-巴格曼-米歇尔-特莱格迪方程研究了电子束极化的演变,发现去极化过程受注入方案的影响。在横向自注入的情况下,正如在典型的气泡机制中发现的那样,加速电子的自旋前驱主要受到唤醒场的影响。然而,在准一维系统中的纵向注入情况下(例如,F. Y. Li 等人,Phys.110, 135002 (2013)),电子自旋方向会在激光场中摆动。由于电子围绕激光轴运动,激光场的净影响几乎为零,因此可以忽略唤醒场的贡献。最后,利用纵向自注入可以获得偏振为99%$的超短电子束。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Generation of polarized electron beams through self-injection in the interaction of a laser with a pre-polarized plasma

Polarized electron beam production via laser wakefield acceleration in pre-polarized plasma is investigated by particle-in-cell simulations. The evolution of the electron beam polarization is studied based on the Thomas–Bargmann–Michel–Telegdi equation for the transverse and longitudinal self-injection, and the depolarization process is found to be influenced by the injection schemes. In the case of transverse self-injection, as found typically in the bubble regime, the spin precession of the accelerated electrons is mainly influenced by the wakefield. However, in the case of longitudinal injection in the quasi-1D regime (for example, F. Y. Li et al., Phys. Rev. Lett. 110, 135002 (2013)), the direction of electron spin oscillates in the laser field. Since the electrons move around the laser axis, the net influence of the laser field is nearly zero and the contribution of the wakefield can be ignored. Finally, an ultra-short electron beam with polarization of $99\%$ can be obtained using longitudinal self-injection.

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来源期刊
High Power Laser Science and Engineering
High Power Laser Science and Engineering Physics and Astronomy-Nuclear and High Energy Physics
CiteScore
7.10
自引率
4.20%
发文量
401
审稿时长
21 weeks
期刊介绍: High Power Laser Science and Engineering (HPLaser) is an international, peer-reviewed open access journal which focuses on all aspects of high power laser science and engineering. HPLaser publishes research that seeks to uncover the underlying science and engineering in the fields of high energy density physics, high power lasers, advanced laser technology and applications and laser components. Topics covered include laser-plasma interaction, ultra-intense ultra-short pulse laser interaction with matter, attosecond physics, laser design, modelling and optimization, laser amplifiers, nonlinear optics, laser engineering, optical materials, optical devices, fiber lasers, diode-pumped solid state lasers and excimer lasers.
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