Microtearing modes in tokamak discharges
Artikel i vetenskaplig tidskrift, 2016
Microtearing modes (MTMs) have been identified as a source of significant electron thermal
transport in tokamak discharges. In order to describe the evolution of these discharges, it is
necessary to improve the prediction of electron thermal transport. This can be accomplished by
utilizing a model for transport driven by MTMs in whole device predictive modeling codes. The
objective of this paper is to develop the dispersion relation that governs the MTM driven transport.
A unified fluid/kinetic approach is used in the development of a nonlinear dispersion relation for
MTMs. The derivation includes the effects of electrostatic and magnetic fluctuations, arbitrary
electron-ion collisionality, electron temperature and density gradients, magnetic curvature, and the
effects associated with the parallel propagation vector. An iterative nonlinear approach is used to
calculate the distribution function employed in obtaining the nonlinear parallel current and the nonlinear
dispersion relation. The third order nonlinear effects in magnetic fluctuations are included,
and the influence of third order effects on a multi-wave system is considered. An envelope equation
for the nonlinear microtearing modes in the collision dominant limit is introduced in order to obtain
the saturation level. In the limit that the mode amplitude does not vary along the field line, slab geometry,
and strong collisionality, the fluid dispersion relation for nonlinear microtearing modes is
found to agree with the kinetic dispersion relation. Published by AIP Publishing.
[http://dx.doi.org/10.1063/1.4953609]
I. INTRODUCTION
Micro-instabilities can result in turbulence that influences
energy confinement in tokamak discharges. One such
micro-instability is the microtearing mode (MTM), a
tearing-parity mode centered on high-order rational surfaces.
Microtearing instability can provide a significant contribution
to the electron thermal transport in low-aspect ratio
tokamaks.1–5 The MTMs lead to a tearing and subsequent
reconnection of the magnetic field. MTMs are shortwavelength
ion scale (low kh) electromagnetic instabilities
that are driven by electron temperature gradients.6–8 It was
proposed that when the magnetic field has a component in
the same direction as the electron temperature gradient, a
current is driven in the direction of the magnetic field line,
which can destabilize MTMs. These modes propagate in the
electron diamagnetic drift direction and depend on the electron
ion collisionality.9,10 Consequently, transport driven by
MTM instabilities depends on both the electron ion collision
frequency and the electron temperature gradient. The
research carried out in this paper indicates that when the
electrostatic effects are included, MTMs also depend on the
density gradient.
Turbulent transport
magnetic islands