A family of quasi-axisymmetric stellarators with varied rotational transform

Abstract

We apply a continuation method to recently optimized stellarator equilibria with excellent quasi-axisymmetry (QA) to generate new equilibria with a wide range of rotational transform profiles. Using these equilibria, we investigate how the rotational transform affects fast-particle confinement, the maximum coil-plasma distance, the maximum growth rate in linear gyrokinetic ion-temperature gradient (ITG) simulations, and the ion heat flux in corresponding nonlinear simulations. We find values of two-term quasisymmetry error comparable to or lower than the similar Landreman-Paul (Phys. Rev. Lett. 128, 035001) configuration for values of the mean rotational transform between 0.12 and 0.75. The fast-particle confinement improves with until = 0.73, at which point the degradation in quasisymmetry outweighs the benefits of further increasing . The required coil-plasma distance only varies by about 10\% for the configurations under consideration, and is between 2.8\,m to 3.3\,m when the configuration is scaled up to reactor size. The maximum growth rate from linear gyrokinetic simulations increases with , but also shifts towards higher ky values. The maximum linear growth rate is sensitive to the choice of flux tube at rational , but this can be compensated for by taking the maximum over several flux tubes. The corresponding ion heat fluxes from nonlinear simulations display a non-monotonic relation to . Sufficiently large positive shear is destabilizing. This is reflected both in linear growth rates and nonlinear heat fluxes.