Ultra-high charge electron acceleration for nuclear applications

Fundamental Plasma Physics Pub Date : 2024-08-30 DOI:10.1016/j.fpp.2024.100071

Liming Chen, Jie Feng, Wenchao Yan, Hao Xu, Yaojun Li, Wenzhao Wang, Xulei Ge, Xiaojun Huang, Jie Zhang

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Abstract

Ultra-intense laser-plasma wakefield accelerator possess several superior properties compared with the traditional radio-frequency accelerators. These characteristics include femtosecond duration, micro-source size, and ultra-dense beam density, result in highly advantageous for various important applications. In this paper, we reviewed the generation of ultra-intense and high charge electron beam based on laser-plasma acceleration and its nuclear applications in Shanghai Jiao Tong University, including the production of 10 s nC charge beams, the generation of ultra-high flux neutron source on the order of 10¹⁹ n/cm²/s, and the excitation of nuclear isomers with the peak efficiency on the order of 10¹⁵ particle/s. This laser driving ultra-dense electron source, in conjunction with the plasma environment, presents immense potential in addressing critical problems in astrophysics, and facilitating various nuclear applications. Based on above progress in nuclear astrophysics, a new research plateform about laboratory astrophysics with a 2.5 PW laser will be constructed in TDLI institute.

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用于核应用的超高电荷电子加速器

与传统的射频加速器相比，超强激光等离子体唤醒场加速器具有多种优越性能。这些特性包括飞秒持续时间、微源尺寸和超密集电子束密度，因此在各种重要应用中具有极大的优势。本文综述了上海交通大学基于激光等离子体加速技术的超强高电荷电子束的产生及其在核领域的应用，包括产生10 s nC电荷束、产生1019 n/cm2/s数量级的超高通量中子源，以及以1015粒子/s数量级的峰值效率激发核异构体。这种激光驱动的超密集电子源与等离子体环境相结合，在解决天体物理学的关键问题和促进各种核应用方面具有巨大潜力。在核天体物理学取得上述进展的基础上，将在 TDLI 研究所建造一个配备 2.5 PW 激光器的实验室天体物理学研究平台。

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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Fundamental Plasma Physics

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