Evolution of Weak Shock Waves in Perfectly Conducting Gases

DOI: 10.4236/am.2011.25086   PDF   HTML     4,951 Downloads   9,050 Views   Citations


This article aims at studying one dimensional unsteady planar and cylindrically symmetric flow involving shocks under the influence of magnetic field. The method of generalized wavefront expansion (GWE) is employed to derive a coupled system of nonlinear transport equations for the jump of field variables and of its spatial derivatives across the shock, which, in turn determine the evolution of wave amplitude and admit a solution that agrees with the classical decay laws of weak shocks. A closed form solution exhibiting the features of nonlinear steepening of the wave front. A general criterion for a compression wave to steepen into a shock is derived. An analytic expression elucidating how the shock formation distance is influenced by the magnetic field strength is obtained. Also, the effects of geometrical spreading and nonlinear convection on the distortion of the waveform are investigated in the presence of magnetic field.

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L. Singh, D. Singh and S. Ram, "Evolution of Weak Shock Waves in Perfectly Conducting Gases," Applied Mathematics, Vol. 2 No. 5, 2011, pp. 653-660. doi: 10.4236/am.2011.25086.

Conflicts of Interest

The authors declare no conflicts of interest.


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