Measurement of magnetic cavitation driven by heat flow in a plasma

In extreme pressures and temperature gradients, heat flow and magnetic fields are strongly coupled, but although theoretical work shows that strong heat flows can cause significant changes in the magnetic field, it has long proven difficult to measure these changes experimentally. Here we describe the first direct measurement of Nernst-driven magnetic cavitation, in which heat flow causes expulsion of the magnetic field from the hottest regions of a plasma. Using laser-driven proton radiography, we demonstrate that Nernst advection dominates changes to the magnetic field in underdense plasmas on these nanosecond timescales. Due to the increased magnetic field strength at the edge of the hot plasma, the observed magnetic cavitation can be accurately described by fluid models of heat flow, despite mean free paths much longer than the temperature gradient. Expulsion of the magnetic field from hot regions of the plasma reduces the effectiveness of magnetised fusion techniques and disrupts magnetised plasma experiments.