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Physical Science International Journal, ISSN: 2348-0130,Vol.: 8, Issue.: 2

Original-research-article

The Effect of Suspended Particles on Magneto- Gravitational Instability under the Influence of Electrical Resistivity

 

R. K. Pensia1, A. K. Patidar2 and V. Shrivastava2*

1Department of Physics, Government Girls College, Neemuch (M.P.), 458441, India.

2Department of Physics, Pacific University, Udaipur (Raj.), 313024, India.

Article Information
Editor(s):
(1) Christian Brosseau, Distinguished Professor, Department of Physics, Université de Bretagne Occidentale, France.
Reviewers:
(1) Rhi, Seok-Ho, Chungbuk National University, South Korea.
(2) Sajjad Hussain, Govt. Postgraduate College Layyah, Punjab, Pakistan.
Complete Peer review History: http://sciencedomain.org/review-history/11801

Abstracts

The problem of magneto-gravitational instability of rotating viscous, electrical conducting medium in the presence of suspended particles is studied Incorporating, thermal conductivity, and radiative heat-loss function. The Normal mode analysis is applied to derive the dispersion relation and it is discussed for wave propagation in longitudinal and transverse direction. Applying Routh-Hurwitz criterion the stability of the medium is discussed. The effect of suspended particles, magnetic field, rotation, resistivity and viscosity, Jean’s criterion determines the condition of gravitational instability of gas particle medium. From the curves, we find that the effect of suspended particles, viscosity and temperature dependent heat-loss function have a stabilizing effect while density dependent heat-loss function has a destabilizing influence on the growth rate of an instability.

Keywords :

Rotation; finite electrical resistivity; radiation; suspended particles and thermal conductivity.

Full Article - PDF    Page 1-14

DOI : 10.9734/PSIJ/2015/10254

Review History    Comments

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