Title :
Two-dimensional MHD simulation of isothermal plasma armatures
Author :
Boynton, G.C. ; Huerta, M.A.
Author_Institution :
Dept. of Phys., Miami Univ., Coral Gables, FL, USA
fDate :
6/1/1989 12:00:00 AM
Abstract :
The authors report results on the use of a two-dimensional resistive MHD code to simulate the internal dynamics in a railgun plasma armature, starting from a slightly perturbed equilibrium initial state. The plasma temperature, conductivity, and ionization fractions are treated as uniform in space and constant in time. The rear of the plasma is in contact with a low-pressure nonconducting gas. A finite-difference, explicit, Eulerian, flux-corrected transport code is used to advance all quantities in time. The computation grid has 200 cells parallel to the rails, and 20 across the rails. The results show the growth and subsequent shedding of the plasma mass toward the nonconducting region at the rear. The mass lost is not replenished and the armature becomes shorter, with steeper pressure and magnetic field profiles. The bulk of the profiles is not thoroughly disrupted, but behaves rather sturdily and seems to maintain a shape fairly close to the equilibrium profiles
Keywords :
electromagnetic launchers; plasma magnetohydrodynamics; plasma simulation; plasma temperature; plasma transport processes; MHD simulation; computation grid; conductivity; equilibrium profiles; flux-corrected transport code; growth; internal dynamics; ionization fractions; isothermal plasma armatures; low-pressure nonconducting gas; magnetic field profiles; plasma mass; plasma temperature; pressure; railgun plasma armature; slightly perturbed equilibrium initial state; space; time; two-dimensional resistive MHD code; Conductivity; Finite difference methods; Ionization; Isothermal processes; Magnetohydrodynamics; Plasma simulation; Plasma temperature; Plasma transport processes; Railguns; Rails;
Journal_Title :
Plasma Science, IEEE Transactions on
