Laser-plasma acceleration beyond wave breaking

J. Palastro, B. Malaca, J. Vieira, D. Ramsey, T. Simpson, P. Franke, J. Shaw, D. Froula
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引用次数: 8

Abstract

Laser wakefield accelerators rely on the extremely high electric fields of nonlinear plasma waves to trap and accelerate electrons to relativistic energies over short distances. When driven strongly enough, plasma waves break, trapping a large population of the background electrons that support their motion. This limits the maximum electric field. Here we introduce a novel regime of plasma wave excitation and wakefield acceleration that removes this limit, allowing for arbitrarily high electric fields. The regime, enabled by spatiotemporal shaping of laser pulses, exploits the property that nonlinear plasma waves with superluminal phase velocities cannot trap charged particles and are therefore immune to wave breaking. A laser wakefield accelerator operating in this regime provides energy tunability independent of the plasma density and can accommodate the large laser amplitudes delivered by modern and planned high-power, short pulse laser systems.
超越破波的激光等离子体加速
激光尾流场加速器依靠非线性等离子体波的极高电场,在短距离内捕获并加速电子到相对论能量。当受到足够强的驱动时,等离子体波就会破裂,从而捕获大量支持它们运动的背景电子。这限制了最大电场。在这里,我们引入了一种新的等离子体波激发和尾流场加速制度,消除了这一限制,允许任意高的电场。该机制通过激光脉冲的时空成形实现,利用了具有超光速相速度的非线性等离子体波不能捕获带电粒子的特性,因此不受波破溃的影响。在这种状态下运行的激光尾流场加速器提供了独立于等离子体密度的能量可调性,并且可以适应现代和计划中的高功率短脉冲激光系统提供的大激光振幅。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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