A family of quasi-axisymmetric stellarators with varied rotational transform

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Buller, S., Landreman, M., Kappel, J., & Gaur, R. (2025). A family of quasi-axisymmetric stellarators with varied rotational transform.�Journal of Plasma Physics,�91(1), E18. doi:10.1017/S0022377824001351

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We apply a continuation method to recently optimized stellarator equilibria with excellent quasi-axisymmetry 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 simulations and the ion heat flux in corresponding nonlinear simulations. We find values of two-term quasi-symmetry error comparable to or lower than those of the similar Landreman�Paul ( Phys. Rev. Lett. , vol. 128, 2022, 035001) configuration for values of the mean rotational transform $bar {iota }$ between $0.12$ and $0.75$ . The fast-particle confinement improves with $bar {iota }$ until $bar {iota } = 0.73$ , at which point the degradation in quasi-symmetry outweighs the benefits of further increasing $bar {iota }$ . The required coil�plasma distance only varies by about ${pm }10,%$ for the configurations under consideration, and is between $2.8$ and $3.3 mathrm {m}$ when the configuration is scaled up to reactor size (minor radius $a=1.7 mathrm {m}$ and volume-averaged magnetic field strength of $5.86 mathrm {T}$ ). The maximum growth rate from linear gyrokinetic simulations increases with $bar {iota }$ , but also shifts towards higher $k_y$ values. The maximum linear growth rate is sensitive to the choice of flux tube at rational $bar {iota }$ , 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 $bar {iota }$ . Sufficiently large positive shear is destabilizing. This is reflected in both linear growth rates and nonlinear heat fluxes.

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Attribution 4.0 International
https://creativecommons.org/licenses/by/4.0/