Prof Michael Barnes

Momentum injection in tokamak plasmas and transitions to reduced transport.

Physical review letters 106:11 (2011) 115004

Authors:

FI Parra, M Barnes, EG Highcock, AA Schekochihin, SC Cowley

Abstract:

The effect of momentum injection on the temperature gradient in tokamak plasmas is studied. A plausible scenario for transitions to reduced transport regimes is proposed. The transition happens when there is sufficient momentum input so that the velocity shear can suppress or reduce the turbulence. However, it is possible to drive too much velocity shear and rekindle the turbulent transport. The optimal level of momentum injection is determined. The reduction in transport is maximized in the regions of low or zero magnetic shear.

Sources of intrinsic rotation in the low flow ordering

(2011)

Authors:

Felix I Parra, Michael Barnes, Peter J Catto

Up-down symmetry of the turbulent transport of toroidal angular momentum in tokamaks

(2011)

Authors:

Felix I Parra, Michael Barnes, Arthur G Peeters

AstroGK: Astrophysical gyrokinetics code

Journal of Computational Physics Elsevier 229:24 (2010) 9347-9372

Authors:

Ryusuke Numata, Gregory G Howes, Tomoya Tatsuno, Michael Barnes, William Dorland

Transport bifurcation in a rotating tokamak plasma.

Physical review letters 105:21 (2010) 215003

Authors:

EG Highcock, M Barnes, AA Schekochihin, FI Parra, CM Roach, SC Cowley

Abstract:

The effect of flow shear on turbulent transport in tokamaks is studied numerically in the experimentally relevant limit of zero magnetic shear. It is found that the plasma is linearly stable for all nonzero flow shear values, but that subcritical turbulence can be sustained nonlinearly at a wide range of temperature gradients. Flow shear increases the nonlinear temperature gradient threshold for turbulence but also increases the sensitivity of the heat flux to changes in the temperature gradient, except over a small range near the threshold where the sensitivity is decreased. A bifurcation in the equilibrium gradients is found: for a given input of heat, it is possible, by varying the applied torque, to trigger a transition to significantly higher temperature and flow gradients.