Hybrid Simulation Of Alfvén Wave Parametric Decay Instability In Laboratory Plasmas

2022 IEEE International Conference on Plasma Science (ICOPS) Pub Date : 2022-05-22 DOI:10.1109/ICOPS45751.2022.9813237

Feiyu Li, Xiangrong Fu, S. Dorfman

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Abstract

Nonlinear Alfvén waves are subject to parametric instabilities. The parametric decay instability (PDI) is of special interest as it produces backward propagating Alfvén waves which may trigger turbulence development and generates compressible waves which may cause plasma heating. Despite the significant implications, the PDI process has not been directly verified. Recent experiments on the Large Plasma Device (LAPD) showed a modulational-like instability [1] . However, the PDI was missing despite its significant growth rates under the conditions investigated. To resolve the puzzle, we are developing hybrid simulation capabilities to investigate the LAPD-type experiments with realistic geometry and physics conditions. As a first step, we relax the usual periodic boundary conditions and study the PDI of an Alfvén wave packet in a large system under an absorption boundary [2] . We further consider the LAPD-like wave injection and outline the conditions required for observing the PDI in a laboratory plasma [3] . These results may guide the first laboratory verification of the fundamental PDI physics and shed lights on several problems in the heliosphere such as corona/solar-wind heating.

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实验室等离子体中alfvsamn波参量衰减不稳定性的混合模拟

非线性alfvsamn波具有参数不稳定性。参数衰减不稳定性(PDI)产生可能引发湍流发展的向后传播的alfvsamn波和可能引起等离子体加热的可压缩波，因此具有特殊的意义。尽管具有重大意义，但PDI过程尚未得到直接核实。最近在大等离子体装置(LAPD)上的实验显示出一种类似调制的不稳定性。然而，在调查的条件下，尽管PDI有显著的增长，但它却不见了。为了解决这个难题，我们正在开发混合模拟功能，以研究具有真实几何和物理条件的lapd型实验。作为第一步，我们放宽了通常的周期边界条件，研究了吸收边界[2]下大系统中alfvsamn波包的PDI。我们进一步考虑了lapd样波注入，并概述了在实验室等离子体[3]中观察PDI所需的条件。这些结果可能会指导PDI基础物理的第一次实验室验证，并为日冕/太阳风加热等日球层的几个问题提供线索。

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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2022 IEEE International Conference on Plasma Science (ICOPS)

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