Dephasing of ion beams as Magnetic Vortex Acceleration regime transitions into a bubble-like field structure

arXiv - PHYS - Plasma Physics Pub Date : 2024-09-13 DOI:arxiv-2409.09156

Sahel Hakimi, Stepan S. Bulanov, Axel Huebl, Lieselotte Obst-Huebl, Kei Nakamura, Anthony Gonsalves, Thomas Schenkel, Jeroen van Tilborg, Jean-Luc Vay, Carl B. Schroeder, Eric Esarey, Cameron R. Geddes

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Abstract

The interaction of an ultra-intense laser pulse with a near critical density target results in the formation of a plasma channel, a strong azimuthal magnetic field and moving vortices. An application of this is the generation of energetic and collimated ion beams via Magnetic Vortex Acceleration. The optimized regime of Magnetic Vortex Acceleration is becoming experimentally accessible with new high intensity laser beamlines coming online and advances made in near critical density target fabrication. The robustness of the acceleration mechanism with realistic experimental conditions is examined with three-dimensional simulations. Of particular interest is the acceleration performance with different laser temporal contrast conditions, in some cases leading to pre-expanded target profiles prior to the arrival of the main pulse. Preplasma effects on the structure of the accelerating fields is explored, including a detailed analysis of the ion beam properties and the efficiency of the process. Improved scaling laws for the MVA mechanism, including the laser focal spot size effects, are presented.

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磁涡流加速系统过渡到气泡状场结构时离子束的消相现象

超强激光脉冲与接近临界密度的目标相互作用，会形成等离子通道、强方位磁场和运动涡流。其应用之一是通过磁漩涡加速产生能量和准直的离子束。随着新的高强度激光光束线的投入使用和近临界密度靶制造技术的进步，磁漩涡加速的优化机制正在变得可以在实验中使用。我们通过三维模拟研究了加速机制在现实实验条件下的稳健性。特别感兴趣的是不同激光时间对比条件下的加速性能，在某些情况下，会导致在主脉冲到来之前预先扩展目标轮廓。提出了包括激光焦点尺寸效应在内的 MVA 机制的改进缩放定律。

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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arXiv - PHYS - Plasma Physics

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