Effect of finite ion Larmor radius on the Kelvin–Helmholtz instability

Hirosh Nagano

doi:10.1017/S0022377800021450

Abstract

The effect of finite ion Larmor radius on the Kelvin–Helmholtz instability is investigated in the cases of an incompressible and a compressible plasma. When a wave vector is perpendicular to a uniform magnetic field, the effect of finite Larmor radius (FLR) stabilizes perturbations with a wavenumber exceeding a critical value, while there exists another case that the FLR effect destabilizes still more than the usual MHD approximation. The difference between these cases is decided from the configuration of flow velocity and magnetic field. When a wave vector is parallel to a magnetic field, the FLR effect tends to stabilize perturbations with a larger wavenumber.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Nagano, H. 1979. Effect of finite ion larmor radius on the Kelvin-Helmholtz instability of the magnetopause. Planetary and Space Science, Vol. 27, Issue. 6, p. 881.

Sharma, R. C. and Sunil 1995. Thermal instability of a compressible finite Larmor radius, Hall plasma in porous medium. Physics of Plasmas, Vol. 2, Issue. 6, p. 1886.

Sharma, R. C. and Sunil 1996. Thermal instability of a compressible finite-Larmor-radius Hall plasma in a porous medium. Journal of Plasma Physics, Vol. 55, Issue. 1, p. 35.

Sharma, Veena and Rana, Gian Chand 2000. Thermal Instability of a Finite-Larmor-Radius Hall Plasma Under Rotation and Variable Gravitational Field in Porous Medium. Journal of Non-Equilibrium Thermodynamics, Vol. 25, Issue. 2,

Terada, N. Machida, S. and Shinagawa, H. 2002. Global hybrid simulation of the Kelvin–Helmholtz instability at the Venus ionopause. Journal of Geophysical Research: Space Physics, Vol. 107, Issue. A12,

Penz, T. Erkaev, N.V. Biernat, H.K. Lammer, H. Amerstorfer, U.V. Gunell, H. Kallio, E. Barabash, S. Orsini, S. Milillo, A. and Baumjohann, W. 2004. Ion loss on Mars caused by the Kelvin–Helmholtz instability. Planetary and Space Science, Vol. 52, Issue. 13, p. 1157.

Fujimoto, M. Baumjohann, W. Kabin, K. Nakamura, R. Slavin, J. A. Terada, N. and Zelenyi, L. 2007. Hermean Magnetosphere-Solar Wind Interaction. Space Science Reviews, Vol. 132, Issue. 2-4, p. 529.

Fujimoto, M. Baumjohann, W. Kabin, K. Nakamura, R. Slavin, J. A. Terada, N. and Zelenyi, L. 2008. Mercury. Vol. 26, Issue. , p. 347.

Prajapati, R P Chhajlani, R K and Parihar, A K 2010. Kelvin-Helmholtz instability of anisotropic magnetized plasma using generalized polytrope laws. Journal of Physics: Conference Series, Vol. 208, Issue. , p. 012077.

Sundberg, T. Boardsen, S.A. Slavin, J.A. Blomberg, L.G. and Korth, H. 2010. The Kelvin–Helmholtz instability at Mercury: An assessment. Planetary and Space Science, Vol. 58, Issue. 11, p. 1434.

Prajapati, R. P. and Chhajlani, R. K. 2010. Effect of pressure anisotropy and flow velocity on Kelvin–Helmholtz instability of anisotropic magnetized plasma using generalized polytrope laws. Physics of Plasmas, Vol. 17, Issue. 11,

Henri, P. Cerri, S. S. Califano, F. Pegoraro, F. Rossi, C. Faganello, M. Šebek, O. Trávníček, P. M. Hellinger, P. Frederiksen, J. T. Nordlund, A. Markidis, S. Keppens, R. and Lapenta, G. 2013. Nonlinear evolution of the magnetized Kelvin-Helmholtz instability: From fluid to kinetic modeling. Physics of Plasmas, Vol. 20, Issue. 10,

Sundberg, Torbjörn 2017. Dawn‐Dusk Asymmetries in Planetary Plasma Environments. p. 337.

Faganello, Matteo and Califano, Francesco 2017. Magnetized Kelvin–Helmholtz instability: theory and simulations in the Earth’s magnetosphere context. Journal of Plasma Physics, Vol. 83, Issue. 6,

Aizawa, Sae Delcourt, Dominique and Terada, Naoki 2018. Sodium Ion Dynamics in the Magnetospheric Flanks of Mercury. Geophysical Research Letters, Vol. 45, Issue. 2, p. 595.

Cerri, S. S. 2018. Finite-Larmor-radius equilibrium and currents of the Earth’s flank magnetopause. Journal of Plasma Physics, Vol. 84, Issue. 5,

Sharma, A. Y. and McMillan, B. F. 2020. Solving gyrokinetic systems with higher-order time dependence. Journal of Plasma Physics, Vol. 86, Issue. 4,

Kaweeyanun, N. Masters, A. and Jia, X. 2021. Analytical Assessment of Kelvin‐Helmholtz Instability Growth at Ganymede's Upstream Magnetopause. Journal of Geophysical Research: Space Physics, Vol. 126, Issue. 8,

Zhang, Xiao Liu, Yu Lei, Jiuhou Huang, Kexin Jin, Rong and Dang, Tong 2023. Laboratory study of Kelvin–Helmholtz instability at ion kinetic scales. Physics of Plasmas, Vol. 30, Issue. 4,

Tarvus, Vertti Turc, Lucile Zhou, Hongyang Nakamura, Takuma Settino, Adriana Blasl, Kevin Cozzani, Giulia Ganse, Urs Pfau-Kempf, Yann Alho, Markku Battarbee, Markus Bussov, Maarja Dubart, Maxime Gordeev, Evgeniy Tesema Kebede, Fasil Papadakis, Konstantinos Suni, Jonas Zaitsev, Ivan and Palmroth, Minna 2024. Hybrid-Vlasov Modelling of Ion Velocity Distribution Functions Associated with the Kelvin–Helmholtz Instability with a Density and Temperature Asymmetry. The Astrophysical Journal, Vol. 974, Issue. 1, p. 62.

Article contents

Effect of finite ion Larmor radius on the Kelvin–Helmholtz instability

Abstract

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Effect of finite ion Larmor radius on the Kelvin–Helmholtz instability

Abstract

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References

REFERENCES

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