TEM turbulence optimisation in stellarators

TL;DR

This paper introduces a new method to optimize stellarator magnetic configurations for reduced TEM turbulence using a proxy function, leading to lower turbulence and heat flux in the optimized design.

Contribution

It develops a proxy-based optimization approach for TEM turbulence reduction in stellarators, demonstrated on HSX, without extensive turbulence simulations.

Findings

Reduced linear growth rates across operational parameters.

Lower turbulent heat flux in the optimized configuration.

Validation of proxy-based optimization for turbulence control.

Abstract

With the advent of neoclassically optimised stellarators, optimising stellarators for turbulent transport is an important next step. The reduction of ion-temperature-gradient-driven turbulence has been achieved via shaping of the magnetic field, and the reduction of trapped-electron mode (TEM) turbulence is adressed in the present paper. Recent analytical and numerical findings suggest TEMs are stabilised when a large fraction of trapped particles experiences favourable bounce-averaged curvature. This is the case for example in Wendelstein 7-X [C.D. Beidler $\textit{et al}$ Fusion Technology $\bf{17}$, 148 (1990)] and other Helias-type stellarators. Using this knowledge, a proxy function was designed to estimate the TEM dynamics, allowing optimal configurations for TEM stability to be determined with the STELLOPT [D.A. Spong $\textit{et al}$ Nucl. Fusion $\bf{41}$, 711 (2001)] code without extensive turbulence simulations. A first proof-of-principle optimised equilibrium stemming from the TEM-dominated stellarator experiment HSX [F.S.B. Anderson $\textit{et al}$, Fusion Technol. $\bf{27}$, 273 (1995)] is presented for which a reduction of the linear growth rates is achieved over a broad range of the operational parameter space. As an important consequence of this property, the turbulent heat flux levels are reduced compared with the initial configuration.