Effect of the Plasma Pressure on Magnetohydrodynamic Kink Instability in a Cylindrical Geometry 被引量：10

Effect of the Plasma Pressure on Magnetohydrodynamic Kink Instability in a Cylindrical Geometry

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摘要 A semi-analytical method is introduced to study kink instability in cylindrical plasma with line-tied boundary conditions. The method is based on an expansion for magnetohydrodynamics （MHD） equations in one-dimensional （1D） radial eigenvalue problems by using Fourier transforms. The MHD equations then become an ordinary differential equation. This method is applicable to both ideal and non-ideal MHD problem. The effect of plasma pressure （P0） on kink instability is studied in a cylindrical geometry. Complex discrete spectra are pre- sented. Two-dimensional （2D） eigenfunctions with the line-tied boundary conditions are obtained. The growth rate and radial eigenfunctions are different in the two cases of P0 = 0 and P0 ≠ 0, which indicate that the effect of plasma pressure can not be ignored if it is large enough. This method allows us to understand the role of individual radial eigenfunctions, and is also computationally efficient compared to direct solutions of the MHD equations by the finite difference method. A semi-analytical method is introduced to study kink instability in cylindrical plasma with line-tied boundary conditions. The method is based on an expansion for magnetohydrodynamics （MHD） equations in one-dimensional （1D） radial eigenvalue problems by using Fourier transforms. The MHD equations then become an ordinary differential equation. This method is applicable to both ideal and non-ideal MHD problem. The effect of plasma pressure （P0） on kink instability is studied in a cylindrical geometry. Complex discrete spectra are pre- sented. Two-dimensional （2D） eigenfunctions with the line-tied boundary conditions are obtained. The growth rate and radial eigenfunctions are different in the two cases of P0 = 0 and P0 ≠ 0, which indicate that the effect of plasma pressure can not be ignored if it is large enough. This method allows us to understand the role of individual radial eigenfunctions, and is also computationally efficient compared to direct solutions of the MHD equations by the finite difference method.

作者代玉杰刘金远王学慧

机构地区 School of Physics and Optoelectronic Technology College of Sciences

出处《Plasma Science and Technology》 SCIE EI CAS CSCD 2009年第3期269-273,共5页 等离子体科学和技术（英文版）

基金 supported by National Basic Research Program of China (No.2008CB717801) National Natural Science Foundation of China (No.10875024) Laboratory of College and University Program of Liaoning Province of China (No.2008S059)

关键词 plasma pressure Fourier transforms MHD kink instability plasma pressure, Fourier transforms, MHD, kink instability

分类号 O53 [理学—等离子体物理] O361.3 [理学—流体力学]

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参考文献18

1Bergerson W F, Forest C B, Fiksel G, et al. 2006, Phys. Rev. Lett., 96:015004
2Hood A W, Priest E R. 1979, At. Energ., 64:303
3Hiroyoshi Amo, Tetsuya Sato, Akira Kageyama, et al. 1995, Phys. Rev. E, 51:R3838
4Solov'ev L S. 1971, At. Energ., 30:14
5LRaadu M A. 1972, Sol. Phys., 22:425
6Kruskal M, Tuck J L. 1958, Proc. R. Soc., A 245:222
7Shafranov V D. 1956, At. Energ., 5:709
8Ryutov D D, Cohen R H, Pearlstein L D. 2004, Phys. Plasmas, 11:4740
9Hegna C C. 2004, Phys. Plasmas, 11:4230
10Ryutov D D, Furno I, Intrator T P, et al. 2006, Phys. Plasmas, 13:032105

同被引文献88

1朱希睿,孟续军.中低温稠密等离子体电子压强的自洽场计算[J].高压物理学报,2004,18(4):333-338. 被引量：3
2代玉杰,刘金远,王学慧.等离子体压强对Line-tied扭曲不稳定性增长率和本征函数的影响[J].核聚变与等离子体物理,2010,30(4):306-311. 被引量：9
3Mok Y,Hoven G V.Resistive Magnetic Tearing in a FiniteLength Pinch[J].Phys Fluids,1982,25(4):636-642.
4Raadu M A.Suppression of the Kink Instability for MagneticFlux Ropes in the Chromosphere[J].Sol Physics,1972,22:425-433.
5Furno I,Intrator T P,Ryutov D D,et al.Curren-t Driven Ro-tating-Kink Mode in a Plasma Column with a Non-Line-TiedFree End[J].Phys Rev Lett,2006,97(1):015002-1-4.
6Meier D L,Koide S,UchidaY.Magnetohydrodynamic Produc-tion of Relativistic Jets[J].Science,2001,291:84-92.
7Li H,Lapenta G,Finn J M,et al.Modeling the Large ScaleStructures ofAstrophysical Jets in theMagnetically DominatedLimit[J].The Astrophysical Journal.2006,643:92-100.
8Longbottom A W,Rickard G J,Craig I J D,et al.MagneticFlux Braiding Force-Free Equilibria and Current Sheets[J].The Astrophysical Journal,1998,500:471-482.
9贝特曼.磁流体力学不稳定性[M].北京:原子能出版社,1982:115.
10徐学桥,霍裕平.托卡马克中宏观束-等离子体扭曲模不稳定性研究[J].物理学报,1986,35(10):1259-1270.

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6代玉杰,王学慧.磁流体径向本征函数的演化规律[J].真空科学与技术学报,2017,37(12):1190-1193. 被引量：3
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1王永久,郭鸿钧.广义相对论磁流体动力学方程及解[J].数学物理学报（A辑）,1990,10(2):200-208. 被引量：1
2Zhijun SHEN,Xiao LI,Jian REN.Comparisons of some difference forms for compressible flow in cylindrical geometry on arbitrary Lagrangian and Eulerian framework[J].Applied Mathematics and Mechanics(English Edition),2016,37(11):1571-1586. 被引量：1
3何树红,戴正德.周期边界条件下磁流体动力学方程的指数吸引子[J].数学研究,1999,32(1):66-73.
4Zhao-xia LIU,Xing-jiang YU.Long Time L^1-behavior for the Incompressible Magneto-hydrodynamic Equations in a Half-space[J].Acta Mathematicae Applicatae Sinica,2016,32(4):933-944.
5Chun Hui ZHOU.Existence of Weak Solutions to the Three-dimensional Steady Compressible Magnetohydrodynamic Equations[J].Acta Mathematica Sinica,English Series,2012,28(12):2431-2442.
6电磁流体动力学方程的若干问题研究[J].中国科技成果,2015,0(8):56-56.
7徐新英.A BLOW-UP CRITERION FOR 3-D NON-RESISTIVE COMPRESSIBLE HEAT-CONDUCTIVE MAGNETOHYDRODYNAMIC EQUATIONS WITH INITIAL VACUUM[J].Acta Mathematica Scientia,2012,32(5):1883-1900. 被引量：1
8邓志红,孙玉良,李富,Rizwan-uddin.改进的节块展开方法求解圆柱几何对流扩散方程[J].计算物理,2013,30(4):475-482. 被引量：1
9ZhangLinghai.STABILITY AND REGULARITY OF SUITABLY WEAK SOLUTIONS ON n－DIMENSIONAL MAGNETOHYDRODYNAMICS EQUATIONS[J].Journal of Partial Differential Equations,2003,16(1):82-96.
10Wen GAO,Zhen-hua GUO,Dong-juan NIU.Global Helically Symmetric Solutions to 3D MHD Equations[J].Acta Mathematicae Applicatae Sinica,2014,30(2):347-358.

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Effect of the Plasma Pressure on Magnetohydrodynamic Kink Instability in a Cylindrical Geometry 被引量：10

参考文献18

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