Initial propagation of impulsively generated converging cylindrical and spherical shock waves

Abstract

An analytical description for the initial phases of collapse of a spherical or cylindrical shock wave in a perfect gas is given in the present paper. The shock wave is initiated by the instantaneous and uniform deposition of a finite quantity of energy per unit surface area at a finite radiusR₀. For the initial shock motion wherex_s= (R_s-R₀)/R₀is small, analytical solutions are obtained by a power-series expansion of the dependent variables inx_s. The classical self-similar solution for a strong planar blast wave is recovered as the present zero-order solution. Non-similar effects arising from both finite shock strengths and the presence of a characteristic lengthR₀are accounted for simultaneously in the present perturbation scheme. The analysis is carried out up to third order inx_s. For very large values of the initiation energy where the shock wave remains strong throughout its collapse, it is found that the present perturbation solution can adequately describe a significant portion of the collapse processes. The solution indicates that the shock decays rather rapidly initially and later begins to accelerate as a result of the additional adiabatic compression of the shocked states due to flow-area convergence. However, for weak initiation where the energy released is small, the present perturbation solution is an asymptotic series and diverges very rapidly as the shock propagates away from the wall. The range of validity then is limited to very small values ofx_s.