Title :
Asymmetry in fast Z-pinches with thin liners
Author :
Lemons, Don S. ; Faehl, Rickey J.
Author_Institution :
Dept. of Phys., Bethel Coll., North Newton, KS, USA
Abstract :
We use a well-known, two-dimensional solution to Laplace´s equation for the vector potential between two perfectly conducting, individually axisymmetric but mutually eccentric, current carrying cylinders to model the geometry and time evolution of an asymmetric Z-pinch. Cylinder eccentricity correlates with an azimuthal variation in the axial current, the magnetic field, and the force on the liner. The asymmetric force sums to a net force tending to restore the inner cylinder to concentricity. Complete pinch compression and concentricity are achieved simultaneously when the initial radius of the inner cylinder Ri(0) is about 2/3 the radius of the outer return current cylinder Ro or, equivalently, when the initial liner inductance per unit length is about 0.82·nH/cm. Compressing the liner onto a finite-sized cylindrical target boosts this critical ratio only up to Ri(0)/Ro≈3/4. Recent and planned liner compression experiments are evaluated according to these criteria.
Keywords :
Laplace equations; Z pinch; magnetostatics; plasma theory; Laplace equation two-dimensional solution; axial current; current carrying cylinders; cylinder eccentricity; fast Z-pinch asymmetry; finite-sized cylindrical target; initial liner inductance; liner force; magnetic field; outer return current cylinder; pinch compression; thin liners; vector potential; Capacitors; Conducting materials; Geometry; Inductance; Laplace equations; Magnetic fields; Physics; Solid modeling; Thermal resistance; Wire; Magnetic compression; Z-pinch; Z-pinch liner;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2004.835965
