Title :
Heating and transport of metal plasma in a vacuum-arc rail gun
Author :
Vijayan, T. ; Venkatramani, N.
Author_Institution :
Beam Technol. Dev. Group, Laser & Plasma Technol. Div., Trombay, India
fDate :
4/1/2004 12:00:00 AM
Abstract :
Arc coupled nonlinear LCR circuit equations were solved simultaneously with the Newtonian arc motion to describe the under-critically damped high arc current and resulting _J × _B propulsion in a vacuum-arc rail gun. Heating of plasma owing to the direct coupling by arc through magneto-hydrodynamic, ion-acoustic, Coulomb, and neutral interactions is formulated in a three-component electron continuity regime including major loss by radiation. The plasma density (ne) so deduced in arc was around 1022-1023m-3, temperature (Te) over hundreds of electronvolts, and attained final velocity ∼2×106cm/s. The launched plasma on emerging from the gun muzzle, rapidly equilibrated through radiative re-combinations and three-body collisions has ne∼5×1021m-3 and Te∼80-90 eV at 50 cm away from the breech as shown through experiments.
Keywords :
plasma collision processes; plasma density; plasma guns; plasma heating; plasma magnetohydrodynamics; plasma temperature; plasma transport processes; railguns; vacuum arcs; 50 cm; Coulomb interaction; Newtonian arc motion; arc coupled nonlinear LCR equations; gun muzzle launched plasma; ion-acoustic interaction; magnetohydrodynamic interaction; metal plasma heating; metal plasma transport; neutral interaction; plasma density; plasma temperature; plasma velocity; radiative loss; radiative recombinations; three-body collisions; three-component electron continuity regime; under-critically damped high arc current; vacuum-arc rail gun; Coupling circuits; Electrons; Heating; Nonlinear equations; Plasma density; Plasma temperature; Plasma transport processes; Propulsion; Rails; Vacuum arcs; Experiments; modeling; plasma heating; rail gun; vacuum-arc propulsion;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2004.828536
