One-dimensional steady-state model for stimulated Raman and Brillouin backscatter processes in laser-irradiated plasmas

IF 1.1 4区物理与天体物理 Q4 PHYSICS, APPLIED Laser and Particle Beams Pub Date : 2020-09-01 DOI:10.1017/s0263034620000191

Z. Ge, G. Zhang, Y. Ke, X. Yang, F. Wu, S. Chen, Yanyun Ma

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Abstract

A one-dimensional steady-state model for stimulated Raman backscatter (SRS) and stimulated Brillouin backscatter (SBS) processes in laser-irradiated plasmas is presented. Based on a novel “predictor-corrector” method, the model is capable to deal with broadband scattered light and inhomogeneous plasmas, exhibiting robustness and high efficiency. Influences of the electron density and temperature on the linear gains of both SRS and SBS are investigated, which indicates that the SRS gain is more sensitive to the electron density and temperature than that of the SBS. For the low-density case, the SBS dominates the scattering process, while the SRS exhibits much higher reflectivity in the high-density case. The nonlinear saturation mechanisms and competition between SRS and SBS are included in our model by a phenomenological method. The typical anti-correlation between SRS and SBS versus electron density is reproduced in the model. Calculations of the reflectivities are qualitatively in agreement with the typical results of experiments and simulations.

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激光辐照等离子体中受激拉曼和布里渊背散射过程的一维稳态模型

建立了激光等离子体受激拉曼后向散射(SRS)和受激布里渊后向散射(SBS)过程的一维稳态模型。该模型基于一种新颖的“预测-校正”方法，能够处理宽带散射光和非均匀等离子体，具有鲁棒性和高效率。研究了电子密度和温度对SRS和SBS线性增益的影响，结果表明SRS增益对电子密度和温度的敏感性高于SBS。在低密度情况下，SBS在散射过程中占主导地位，而在高密度情况下，SRS表现出更高的反射率。采用现象学方法将非线性饱和机制和SRS与SBS之间的竞争纳入模型。该模型再现了SRS和SBS与电子密度之间典型的反相关关系。反射率的计算结果与典型的实验和模拟结果在定性上是一致的。

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.