Direct Optimization of Neoclassical Ion Transport in Stellarator Reactors
Brandon Lee, Columbia University
We directly optimize stellarator neoclassical ion transport while holding electron transport at a moderate level, creating a scenario favorable for impurity expulsion and retaining good ion confinement. Traditional neoclassical stellarator optimization has focused on minimizing ϵeff, the geometric factor that characterizes the amount of radial transport due to particles in the 1/v regime. Under expected reactor-relevant conditions, core electrons will be in the 1/v regime and core fuel ions will be in the √v regime. Traditional optimizations thus minimize electron transport and rely on the radial electric field (Er) that develops to confine the ions. This often results in an inward-pointing Er that drives high-Z impurities into the core, which may be troublesome in future reactors. In our optimizations, we increase the ratio of the thermal transport coefficients Le11/Li11, which previous work has shown can create an outward-pointing Er. This effect is very beneficial for impurity expulsion. We obtain self-consistent density, temperature, and Er profiles at reactor-relevant conditions for optimized equilibria. These equilibria are expected to enjoy significantly improved impurity transport properties.