An Arbitrary-Lagrangian-Eulerian solver for relativistic detonation waves

In this paper we study the dynamics of relativistic detonation waves theoretically and numerically.

The reaction is physically accounted for by an extra term in the definition of the total energy density and by an additional equation for the evolution of the mass fraction of the reactant, while leaving formally unmodified the equations of mass and energy-momentum conservation.

In this way, the Rankine-Hugoniot relations maintain the same formal structure of the inert version.

For the numerical solution we use a second order finite volume ALE scheme with TVD reconstruction, where the mesh velocity is chosen equal to the shock speed.

We also adopt a locally implicit algorithm for the treatment of potentially stiff reaction source terms that arise in the equation of the reactant.

We furthermore propose a particularly efficient algorithm for the conversion from the conserved to the primitive variables, which for the relativistic Euler equations is known to be nontrivial.

Following this approach, we can successfully solve the Zel'dovich-von Neumann-Doering profile of a relativistsic detonation wave, up to Lorentz factors of the shock front $\gamma_S\sim 7$.

Our analysis allowed us to highlight a new special relativistic effect, which has remained unnoticed so far.

While in Newtonian detonations the Zel'dovich pressure jump decreases monotonically with the mass flux through the shock front, in the relativistic case it shows a minimum and then rises monotonically as a function of the mass flux.

This may have interesting physical implications on the amount of energy that can be extracted from a relativistic detonation wave.