Litcius/Paper detail

The universal instability in optimised stellarators

P. Costello, J. H. E. Proll, G. G. Plunk, M. J. Pueschel, J. A. Alcusón

2023Journal of Plasma Physics13 citationsDOIOpen Access PDF

Abstract

In tokamaks and neoclassically optimised stellarators, like Wendelstein 7-X (W7-X) and the Helically Symmetric Experiment, turbulent transport is expected to be the dominant transport mechanism. Among the electrostatic instabilities that drive turbulence, the trapped-electron mode (TEM) has been shown both analytically and in simulations to be absent over large ranges of parameter space in quasi-isodynamic stellarator configurations with the maximum- $J$ property. It has been proposed that the reduction of the linear TEM growth rate in such configurations may lead to the passing-electron-driven universal instability, which is often subdominant to the TEM, becoming the fastest-growing instability over some range of parameter space. Here, we show through gyrokinetic simulations using the Gene code, that the universal instability is dominant in a variety of stellarator geometries over a range of parameter space typically occupied by the TEM, but most consequentially in devices which possess beneficial TEM stability properties like W7-X, which locally satisfies the maximum- $J$ property for deeply trapped particles in the regions of worst curvature. We find that the universal instability exists at long perpendicular wavelengths and, as a result, dominates the potential fluctuation amplitude in nonlinear simulations. In W7-X, universal modes are found to differ in parallel mode structure from trapped-particle modes, which may impact turbulence localisation in experiments.

Topics & Concepts

StellaratorPhysicsInstabilityTurbulenceGyrokineticsParameter spaceWavenumberTokamakCurvatureMechanicsComputational physicsPlasmaOpticsQuantum mechanicsGeometryMathematicsMagnetic confinement fusion researchIonosphere and magnetosphere dynamicsLaser-Plasma Interactions and Diagnostics