Litcius/Paper detail

Extended-magnetohydrodynamics in under-dense plasmas

C. A. Walsh, J. P. Chittenden, Dominic Hill, C. P. Ridgers

2020Physics of Plasmas57 citationsDOIOpen Access PDF

Abstract

Extended-magnetohydrodynamics (MHD) transports magnetic flux and electron energy in high-energy-density experiments, but individual transport effects remain unobserved experimentally. Two factors are responsible in defining the transport: electron temperature and electron current. Each electron energy transport term has a direct analog in magnetic flux transport. To measure the thermally driven transport of magnetic flux and electron energy, a simple experimental configuration is explored computationally using a laser-heated pre-magnetized under-dense plasma. Changes to the laser heating profile precipitate clear diagnostic signatures from the Nernst, cross-gradient-Nernst, anisotropic conduction, and Righi-Leduc heat-flow. With a wide operating parameter range, this configuration can be used in both small and large scale facilities to benchmark MHD and kinetic transport in collisional/semi-collisional, local/non-local, and magnetized/unmagnetized regimes.

Topics & Concepts

PhysicsMagnetohydrodynamicsPlasmaElectron temperatureThermal conductionElectronMagnetic fluxHeat fluxKinetic energyComputational physicsFlux (metallurgy)Magnetic energyMagnetic fieldAtomic physicsMechanicsHeat transferClassical mechanicsNuclear physicsThermodynamicsMagnetizationMaterials scienceMetallurgyQuantum mechanicsMagnetic confinement fusion researchLaser-Plasma Interactions and DiagnosticsIonosphere and magnetosphere dynamics