Dynamics of Ion Temperature Gradient Turbulence and Transport with a Static Magnetic Island

TL;DR

This study investigates how static magnetic islands influence ion temperature gradient turbulence and transport using analytic theory and numerical simulations, revealing threshold effects and localized flux enhancements.

Contribution

It introduces a combined theoretical and simulation approach to analyze the impact of magnetic islands on microturbulence in fusion plasmas, highlighting threshold behaviors and flux localization.

Findings

Island width must exceed a threshold to affect turbulence.

Turbulent fluctuations and heat flux increase with island presence.

Radial ion energy flux localizes near the X-point asymmetrically.

Abstract

Understanding the interaction mechanisms between large-scale magnetohydrodynamic instabilities and small-scale drift-wave microturbulence is essential for predicting and optimizing the performance of magnetic confinement based fusion energy experiments. We report progress on understanding these interactions using both analytic theory and numerical simulations performed with the BOUT++ [B. Dudson et al., Comput. Phys. Comm. 180, 1467 (2009)] framework. This work focuses upon the dynamics of the ion temperature gradient instability in the presence of a background static magnetic island, using a weakly electromagnetic two-dimensional five-field fluid model. It is found that the island width must exceed a threshold size (comparable to the turbulent correlation length in the no-island limit) to significantly impact the turbulence dynamics, with the primary impact being an increase in turbulent fluctuation and heat flux amplitudes. The turbulent radial ion energy flux is shown to localize near the X-point, but does so asymmetrically in the poloidal dimension. An effective turbulent resistivity which acts upon the island outer layer is also calculated, and shown to always be significantly (10x - 100x) greater than the collisional resistivity used in the simulations.