Influence of finite larmor radius correction on magneto gravitational instability of anisotropic quantum plasma

Author

Sharma, P.

Author_Institution

Phys. Dept., Ujjain Eng. Coll., Ujjain, India

fYear

2015

fDate

24-28 May 2015

Firstpage

1

Lastpage

1

Abstract

Summary form only given. The effect of finite Larmor radius correction of ion to the pressure tensor (FLR) and pressure anisotropy is studied on the Jeans instability of self-gravitating quantum magnetohydrodynamic (QMHD) plasma considering linear approximation. The effect of FLR and pressure anisotropy is incorporated in the Fermi degenerate quantum plasma and basic Chew-Goldberger and Low (CGL) equations are modified. The linear QMHD equations including the quantum Bohm potential in the momentum transfer equation of anisotropic plasma, continuity equation and the energy equations are linearized. A linear analytical dispersion relation is obtained using the normal mode analysis. The non-gravitating magnetized mode is obtained which provides the hose instability and it is independent of quantum corrections. The gravitating mode modified due to the quantum corrections is obtained separately. The Jeans criterion of instability is examined and it is found that due to increase in quantum correction parameter the critical Jeans wave number and unstable region decreases. Hence it has destabilizing influence on the growth rate of Jeans instability of self gravitating anisotropic pressure quantum plasma.

Keywords

anisotropic media; dispersion relations; mass transfer; plasma instability; plasma magnetohydrodynamic waves; Chew-Goldberger-and-Low equations; Fermi degenerate quantum plasma; Jeans instability; continuity equation; critical Jeans wave number; energy equations; finite Larmor radius correction; linear QMHD equations; linear analytical dispersion relation; magneto gravitational instability; momentum transfer equation; normal mode analysis; pressure anisotropy; pressure tensor; quantum Bohm potential; self gravitating anisotropic pressure quantum plasma; self-gravitating quantum magnetohydrodynamic plasma; Anisotropic magnetoresistance; Magnetic separation; Perpendicular magnetic anisotropy; Plasmas; Tensile stress; FLR effects; Gravitational instability; Quantum plasma; anisotropic plasma;

fLanguage

English

Publisher

ieee

Conference_Titel

Plasma Sciences (ICOPS), 2015 IEEE International Conference on

Conference_Location

Antalya

Type

conf

DOI

10.1109/PLASMA.2015.7179755

Filename

7179755