Proof of the zeroth law of turbulence in one-dimensional compressible magnetohydrodynamics and shock heating

Vincent David

Laboratoire de Physique des Plasmas -

The zeroth law is one of the oldest conjecture in turbulence that is still unproven. Here, we consider weak solutions of one-dimensional compressible magnetohydrodynamics and demonstrate that the lack of smoothness of the fields introduces a new dissipative term, named inertial dissipation, into the expression of energy conservation that is neither viscous nor resistive in nature. We propose exact solutions assuming that the kinematic viscosity and the magnetic diffusivity are equal, and we demonstrate that the associated inertial dissipation is positive and equal on average to the mean viscous dissipation rate in the limit of small viscosity, proving the conjecture of the zeroth law of turbulence and the existence of an anomalous dissipation. As an illustration, we evaluate the shock heating produced by discontinuities detected by Voyager in the solar wind around 5 AU and deduce that collisionless shocks can be a dominant source of heating in the outer solar wind.

Related paper: https://arxiv.org/pdf/2106.05612.pdf