Effect of triangularity on plasma turbulence and the SOL-width scaling in L-mode diverted tokamak configurations

Abstract

The effect of triangularity on tokamak boundary plasma turbulence is investigated by using global, flux-driven, three-dimensional, two-fluid simulations. The simulations show that negative triangularity stabilizes boundary plasma turbulence, and linear investigations reveal that this is due to a reduction of the magnetic curvature drive of interchange instabilities, such as the resistive ballooning mode. As a consequence, the pressure decay length Lp, related to the SOL power fall-off length λq, is found to be affected by triangularity. Leveraging considerations on the effect of triangularity on the linear growth rate and nonlinear evolution of the resistive ballooning mode, the analytical theory-based scaling law for Lp in L-mode plasmas, derived by Giacomin et al. [Nucl. Fusion, https://doi.org/10.1088/1741-4326/abf8f661 076002 (2021)], is extended to include the effect of triangularity. The scaling is in agreement with nonlinear simulations and a multi-machine experimental database, which include recent TCV discharges dedicated to the study of the effect of triangularity in L-mode diverted discharges. Overall, the present results highlight that negative triangularity narrows the Lp and considering the effect of triangularity is important for a reliable extrapolation of λq from present experiments to larger devices.