Shock‐Wave Structure using Nonlinear Model Boltzmann Equations

The structure of strong plane shock waves in a perfect monatomic gas was studied using four nonlinear models of the Boltzmann equation. The models involved the use of a simplified collision operator with velocity‐independent collision frequency, in place of the complicated Boltzmann collision operator. The models employed were the BGK and ellipsoidal models developed by earlier authors, and the polynomial and trimodal gain function models developed during the work. An exact set of moment equations was derived for the density, velocity, temperature, viscous stress, and heat flux within the shock. This set was reduced to a pair of coupled nonlinear integral equations and solved using specially adapted numerical techniques. A new and simple Gauss‐Seidel iteration was developed during the work and found to be as efficient as the best earlier iteration methods. Extensive comparisons were made of the model results with Monte Carlo solutions, and significant aspects of the comparisons are discussed.