Empirical impact of near-separatrix plasma and neutral transport on the pedestal in the transition between EDA and ELMy H-modes on Alcator C-Mod
Abstract
The transition between the ELMy H-mode and the EDA H-mode is studied on Alcator C-Mod using an experimental database and predictive pedestal models. High-resolution Thomson scattering measurements are used to compare the pedestal density, neped, and the separatrix density, nesep with main chamber neutral measurements. neped is sensitive to neutral sources only in the ELMy H-mode regime and not in the EDA H-mode regime. Density fluctuation spectra reveal that quasi-coherent structures become stronger at higher densities and more coherent in the EDA relative to the inter-ELM phases of ELMy H-modes, before weakening again at the highest values of neped. The Saarelma-Connor pedestal density prediction model is validated for ELMy H-modes up to neped = 2.0 × 1020 m-3. An additional transport channel driven by resistive ballooning modes (RBM), DRBM, scaling directly with αt and inversely with kRBM2qcyl is shown to improve the prediction for EDA H-modes, finding good model agreement up to neped = 3.0 × 1020 m-3. EPED scans in neped are then performed at three values of nesep/neped. Increasing this ratio moves the peeling-ballooning branch transition to lower neped, increasing pped in the peeling branch and decreasing it in the ballooning branch. Agreement is found for large ELM H-modes. SPARC pedestal density predictions for an ELMy and an EDA/QCE-like H-mode are performed and found consistent with assumptions used in previous EPED modeling. Inclusion of DRBM significantly weakens the density gradient near the separatrix, lowering neped by approximately 20%.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.