论文信息 - Plasma size scaling of avalanche-like heat transport in tokamaks

Plasma size scaling of avalanche-like heat transport in tokamaks

The influence of plasma size on global ion temperature gradient turbulence is studied with the full-f Eulerian code GT5D (Idomura et al 2009 Nucl. Fusion 49 065029). The gyrokinetic model includes a consistent neoclassical electric field as well as a fixed-power source operator, enabling long-time simulations with self-consistent turbulent transport and equilibrium profiles. The effects of plasma size (from ρ* = 1/100 to ρ* = 1/225) are studied by scaling the minor radius a and the input power. For the first time, worse-than-Bohm scaling is observed under experimentally realistic conditions. For all plasma sizes, avalanches propagate over significant radii but their propagation depends on the radial electric shear. It is found that this quantity does not scale with ρ* due to the building up of intrinsic momentum. Such a dependence can be inferred from a force balance relation, which remains approximately valid in nonlinear simulations. An adaptive parallel momentum source has been implemented in GT5D to damp the parallel momentum profile. The new scan then reveals that the radial electric shear scales with ρ* while the transport is globally higher. These simulations therefore suggest that intrinsic momentum reduces heat transport. This work also addresses another important issue in gyrokinetics: it is shown that for fixed initial physical parameters the turbulent quasi-steady-state is statistically independent of the initial conditions.

Yasuhiro Idomura | Sébastien Jolliet | S. Jolliet | Y. Idomura

[1] F. Parra,et al. Vorticity and intrinsic ambipolarity in turbulent tokamaks , 2009 .

[2] R. H. Bulmer,et al. Sustained Spheromak Physics Experiment (SSPX): design and physics results , 2012 .

[3] Virginie Grandgirard,et al. Large scale dynamics in flux driven gyrokinetic turbulence , 2010 .

[4] F. Parra,et al. Limitations of gyrokinetics on transport time scales , 2008 .

[5] S. Satake,et al. Benchmark test of drift-kinetic and gyrokinetic codes through neoclassical transport simulations , 2010, Comput. Phys. Commun..

[6] Yasuhiro Idomura,et al. Consequences of profile shearing on toroidal momentum transport , 2011 .

[7] S. Murakami,et al. Spontaneous toroidal rotation driven by the off-diagonal term of momentum and heat transport in the plasma with the ion internal transport barrier in LHD , 2010 .

[8] Shinji Tokuda,et al. Study of ion turbulent transport and profile formations using global gyrokinetic full-f Vlasov simulation , 2009 .

[9] Z. Lin,et al. Size scaling of turbulent transport in magnetically confined plasmas. , 2002, Physical review letters.

[10] I. Calvo,et al. Phase-space Lagrangian derivation of electrostatic gyrokinetics in general geometry , 2010, 1009.0378.

[11] R. M. Magee,et al. Generation and confinement of hot ions and electrons in a reversed-field pinch plasma , 2010 .

[12] F Jenko,et al. System size effects on gyrokinetic turbulence. , 2010, Physical review letters.