Effect of Plasma Sheaths on Earth-Entry Magnetohydrodynamics

IF 1.1 4区工程技术 Q4 ENGINEERING, MECHANICAL

Journal of Thermophysics and Heat Transfer Pub Date : 2023-08-11 DOI:10.2514/1.t6784

B. Parent, Prasanna T. Rajendran, S. Macheret, J. Little, R. W. Moses, C. Johnston, F. Cheatwood

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Abstract

The first study of the full coupling between the aerothermodynamics, the magnetohydrodynamics (MHD), and the plasma sheaths within Earth-entry flows is here performed. The problem addressed herein is representative of a force-generating MHD patch located between the stagnation point and the aft of a capsule entering the Earth’s atmosphere at Mach 34. The reactions are obtained from the Park chemical solver and the transport coefficients from the Gupta–Yos model with modifications. The physical model fully couples the drift–diffusion model for the sheaths to the multispecies Navier–Stokes equations for the plasma flow. The Hall and ion slip effects are taken into consideration within the plasma flow and within the sheaths. The effect of the electrode material on the MHD process is studied. Using thoriated tungsten instead of graphite leads to a thirtyfold increase in the Lorentz forces and also leads to significantly reduced heat fluxes on the cathode. This is attributed to the much higher electrical conductivity of the thoriated tungsten sheath reducing by orders of magnitude the plasma electrical resistance near the surfaces.

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等离子体鞘层对地球入射磁流体力学的影响

首次对地球进入流中的空气热力学、磁流体力学（MHD）和等离子体鞘层之间的完全耦合进行了研究。本文所解决的问题代表了位于滞流点和以34马赫进入地球大气层的太空舱尾部之间的力产生MHD补片。反应是从Park化学求解器中获得的，传输系数是从Gupta–Yos模型中获得的。物理模型将鞘层的漂移-扩散模型与等离子体流的多相Navier-Stokes方程完全耦合。在等离子体流和鞘层内考虑了霍尔效应和离子滑移效应。研究了电极材料对MHD过程的影响。使用钍钨代替石墨会使洛伦兹力增加三倍，也会显著降低阴极上的热通量。这是由于镀钍钨鞘的电导率高得多，使表面附近的等离子体电阻降低了几个数量级。

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

Journal of Thermophysics and Heat Transfer 工程技术-工程：机械

CiteScore

3.50

自引率

19.00%

发文量

审稿时长

3 months

期刊介绍： This Journal is devoted to the advancement of the science and technology of thermophysics and heat transfer through the dissemination of original research papers disclosing new technical knowledge and exploratory developments and applications based on new knowledge. The Journal publishes qualified papers that deal with the properties and mechanisms involved in thermal energy transfer and storage in gases, liquids, and solids or combinations thereof. These studies include aerothermodynamics; conductive, convective, radiative, and multiphase modes of heat transfer; micro- and nano-scale heat transfer; nonintrusive diagnostics; numerical and experimental techniques; plasma excitation and flow interactions; thermal systems; and thermophysical properties. Papers that review recent research developments in any of the prior topics are also solicited.