Local Transport Barrier Formation and Relaxation in Reverse-Shear Plasmas on the TFTR Tokamak
Authors: E.J. Synakowski, S.H. Batha,(a) M.A. Beer, et al.
The roles of turbulence stabilization by sheared EŽB flow and Shafranov-shift gradients are examined for TFTR [Plasma Phys. Controlled Nucl. Fusion Res. 26, 11 (1984)] Enhanced Reverse-Shear plasmas. Both effects in combination provide the basis of a positive-feedback model that predicts reinforced turbulence suppression with increasing pressure gradient. Local fluctuation behavior at the onset of ERS confinement is consistent with this framework. The power required for transitions into the ERS regime are lower when high power neutral beams are applied earlier in the current profile evolution, consistent with the suggestion that both effects play a role. Separation of the roles of EŽB and Shafranov shift effects was performed by varying the EŽB shear through changes in the toroidal velocity with nearly-steady-state pressure profiles. Transport and fluctuation levels increase only when EŽB shearing rates are driven below a critical value that is comparable to the fastest linear growth rates of the dominant instabilities. While a turbulence suppression criterion that involves the ratio of shearing to linear growth rates is in accord with many of these results, the existence of hidden dependencies of the criterion is suggested in experiments where the toroidal field was varied. The forward transition into the ERS regime has also been examined in strongly rotating plasmas. The power threshold is higher with unidirectional injection than with balanced injection.