REVIEW OF EXPERIMENTAL INVESTIGATIONS ON COMPACT TOROIDS AND COMPACT TOKAMAKS USING TS-3 DEVICE

The TS-3 device at the University of Tokyo has been used to produce free boundary spheromaks or spheromak-like compact toroids. Plasma production is accomplished either by Z-theta discharges or by means of magnetized coaxial plasma guns installed at both ends of the device. The plasmas produced have a minor approximate to major radius of about 15 to 20 cm with a natural decay time of about 30 to 50 mu s and a toroidal plasma current of about 30 to 60 kA. A unique feature of TS-3 device is the possession of production regions at both ends of the device, and concequently the ability of producing two adjacent compact toroids which can be merged through magnetic reconnection. Another feature of TS-3 device is the possibility of external application of a toroidal field with the aid of an optional center conductor assembly that can carry an axial current ranging from 0 to +/-80 kA. This construction enables us to produce compact toroidal plasmas of various types from reversed field pinch(RFP) to tokamak in terms of the difference in q profile. The variation of both poloidal plasma current and external toroidal field current permits the change in magnetic configuration of merging plasmas, enabling the reconnection angle to continuously vary from about 20 degrees (tokamak merging) through 90 degrees (cohelicity spheromak merging) to 180 degrees (counter-helicity spheromak merging to produce field reversed configurations(FRC)). When the coaxial guns are installed at both ends of the device in place of the center conductor, a center plasma current can be injected to form flux-core spheromaks (or bumpy z-pinches). Novel research subjects that have emerged from TS-3 experiments are; (1) the investigation of three dimensional effects of magnetic reconnection in laboratory plasmas, (2) the formation of FRC plasmas by a counter-helicity spheromak merging, (3) non-OH production and merging of tight aspect ratio tokamaks, (4) the stabilization of tilt motions of tight aspect ratio tokamaks, and (5) the formation and compression (flux amplification) of free-boundary tilt stabilized flux-core spheromaks.