Scientists Capture First-Ever Images of Plasma Shell Instability in Action
Researchers have experimentally confirmed a decades-old theory about how plasma shells become unstable when compressed by colliding flows. The finding could improve predictive models for inertial confinement fusion—a leading candidate for commercial fusion energy—and refine simulations used in weapons science and astrophysics.
Originaltitel: Experimental Observation of Thin-shell Instability in a Collisionless Plasma
<p>We report on the experimental observation of the instability of a plasma shell, which formed during the expansion of a laser-ablated plasma into a rarefied ambient medium. By means of a proton radiography technique, the evolution of the instability is temporally and spatially resolved on a timescale much shorter than the hydrodynamic one. The density of the thin shell exceeds that of the surrounding plasma, which lets electrons diffuse outward. An ambipolar electric field grows on both sides of the thin shell that is antiparallel to the density gradient. Ripples in the thin shell result in a spatially varying balance between the thermal pressure force mediated by this field and the ram pressure force that is exerted on it by the inflowing plasma. This mismatch amplifies the ripples by the same mechanism that drives the hydrodynamic nonlinear thin-shell instability (NTSI). Our results thus constitute the first experimental verification that the NTSI can develop in colliding flows.</p>