Optimization of laser parameters for proton acceleration using double laser pulses in TNSA mechanism

IF 1.1 4区物理与天体物理 Q4 PHYSICS, APPLIED

Laser and Particle Beams Pub Date : 2020-06-01 DOI:10.1017/s0263034620000063

Saurabh Kumar, D. N. Gupta

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引用次数: 5

Abstract

The energy of protons accelerated by ultra-intense lasers in the target normal sheath acceleration (TNSA) mechanism can be greatly enhanced by the laser parameter optimization. We propose to investigate the optimization of laser parameters for proton acceleration using double laser pulses in TNSA mechanism. The sheath field generation at the rear side of the target is significantly affected by the introduction of second laser pulse in TNSA mechanism, and consequently, the energy of the accelerated protons is also modified. The second laser pulse was introduced with different delays to study its impact on proton acceleration. Our study shows that the interplay of laser intensity and pulse duration of both laser pulses affects the proton acceleration. It was found that the proton maximum energy is the function of both laser intensity and pulse duration. A number of simulations have been performed to obtain maximum proton energy data under different combinations of laser intensity and pulse duration for the two laser pulses. The simulation results account for the underline physics for the proton bunch energy and the sheath field as a function of pulse intensity and pulse delay.

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双脉冲TNSA机制下质子加速激光参数的优化

在靶正常鞘层加速(TNSA)机制中，通过对激光参数的优化，可以大大提高超强激光对质子的加速能量。我们建议在TNSA机制下研究双激光脉冲质子加速的激光参数优化。在TNSA机制中，第二激光脉冲的引入对靶后侧鞘层场的产生有显著影响，从而使加速质子的能量发生改变。以不同的延迟时间引入第二束激光脉冲，研究其对质子加速的影响。我们的研究表明，激光强度和两种激光脉冲的脉冲持续时间的相互作用影响质子的加速。发现质子的最大能量是激光强度和脉冲持续时间的函数。为了获得两种激光脉冲在不同激光强度和脉冲持续时间组合下的最大质子能量数据，进行了大量的模拟。模拟结果解释了质子束能量和鞘层场随脉冲强度和脉冲延迟的基本物理特性。

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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来源期刊

Laser and Particle Beams PHYSICS, APPLIED-

CiteScore

1.90

自引率

11.10%

发文量

审稿时长

1 months

期刊介绍： Laser and Particle Beams is an international journal which deals with basic physics issues of intense laser and particle beams, and the interaction of these beams with matter. Research on pulse power technology associated with beam generation is also of strong interest. Subjects covered include the physics of high energy densities; non-LTE phenomena; hot dense matter and related atomic, plasma and hydrodynamic physics and astrophysics; intense sources of coherent radiation; high current particle accelerators; beam-wave interaction; and pulsed power technology.