On Dual Mechanisms Limiting Density in the Negative Triangularity Tokamak

Achieving high plasma density is essential for maximizing thermonuclear power and thus crucial for realizing economically viable fusion energy; however, this is often constrained by a fundamental density limit. This study investigates the L-mode density limit in negative triangularity (NT) plasmas on the DIII-D tokamak, and the results provide novel insights into this long-standing challenge. We report sustained operations at densities up to 1.8 times the conventional Greenwald limit with 13 MW of auxiliary heating power. Importantly, systematic power scans reveal distinct power scaling relationships for core ($n_{e} \propto P_{\text{SOL}}^{0.27\pm 0.03}$) and edge ($n_{e} \propto P_{\text{SOL}}^{0.42\pm 0.04}$) densities, which suggest different limiting mechanisms at play and point to a more nuanced picture than the traditional paradigm of a single, universal density limit. In this vein, detailed measurements were performed, revealing a complex interplay of macroscopic profiles, radiation patterns, and turbulent transport. Specifically, edge turbulent transport increased as density rose, leading to enhanced divertor radiation and subsequent MARFE onset. The edge density saturated abruptly following MARFE formation. In contrast, the core density continues to increase, ultimately limited by enhanced turbulence that exhibits characteristics of avalanche-like transport. Consistent with enhanced turbulence, toroidal rotation and the $E_r \times B$ flow shear also collapsed approaching the density limit. Taken together, these observations suggest that MARFE dynamics primarily govern the edge density limit, while turbulence-driven transport dominates the core density limit. These results also indicate the feasibility of operations significantly beyond the Greenwald density in high-power NT plasmas. This can potentially be attained through advanced control of core turbulence and MARFEs.