Feasibility of a motional Stark effect system on the TCV tokamak

This paper presents a feasibility study for a motional Stark effect (MSE) [F. M. Levinton , Phys. Rev. Lett. 63, 2060 (1989)] diagnostic on the TCV tokamak. A numerical simulation code has been used to identify the optimal port arrangement and geometrical layout. It predicts the expected measurement accuracy for a range of typical plasma scenarios. With the existing neutral beam injector (NBI) and a detection system based on current day technology, it should be possible to determine the safety factor with an accuracy of the order of 5%. A vertically injected beam through the plasma center would allow one to measure plasmas which are centered above the midplane, a common occurrence in connection with electron cyclotron resonance heating and electron cyclotron current drive experiments. In this case a new and ideally more powerful NBI would be required. (C) 2004 American Institute of Physics.

Feasibility of a motional Stark effect system on the TCV tokamak

An experimental and computational study of tokamak plasma turbulence

Experimental Testing of the European TH1509U 170-GHz 1-MW CW Industrial Gyrotron-Long Pulse Operation

Full conversion from ohmic to runaway electron driven current via massive gas injection in the TCV tokamak

An experimental and computational study of tokamak plasma turbulence

Experimental Testing of the European TH1509U 170-GHz 1-MW CW Industrial Gyrotron-Long Pulse Operation

Full conversion from ohmic to runaway electron driven current via massive gas injection in the TCV tokamak