Advancements in 3D Edge Long-Pulse Tokamak Scenarios with Instability &amp; Transport Control

Dmitriy M Orlov; Nikolas C Logan; Joseph A Snipes; Egemen Kolemen; Carlos Alberto Paz-Soldan; Yueqiang Liu; Heinke G Frerichs; Vasilii Khavin; Zhihong Lin; Xishuo Wei; Yangyang Yu; Ben Zhu; Nils Leuthold; Priyansh Lunia; Francesca M Poli; Mario L. Podesta; Qiming Hu; SeongMoo Yang; SangKyeun Kim; Ricardo Shousha; Cheol-Sik Byun; Jalal Butt; Andy Rothstein; Tyler B Cote; Shuai Gu; Chen Zhao; Xuan Sun; Jonathan Morgan Van Blarcum; Javier H Nicolau; Eric C Howell; Jong-Kyu Park; Jaemin Seo

Advancements in 3D Edge Long-Pulse Tokamak Scenarios with Instability & Transport Control

ORAL

Abstract

Here, we present advancements in enhancing the predictive capabilities of 3D tokamak models and demonstrating 3D field applications for transport and instability control in long-pulse high-performance plasmas. The project focuses on validating the physics basis for predictive ELM suppression, integrating plasma response into core and edge transport models for long-pulse scenario optimizations, and achieving high confinement long pulse in KSTAR using 3D fields. Significant progress in both linear and nonlinear MHD models was made in predicting ELM suppression criteria. Integration efforts include combining linear and neoclassical kinetic-MHD models with SOL transport models to predict heat flux to KSTAR's PFCs. Fast ion transport models are validated through KSTAR's fast ion diagnostics. Integration of M3D-C1 and GTC provides gyrokinetic simulations of microturbulent transport with magnetic islands. Adaptive real-time control and optimization of 3D fields, combined with pre-programmed stability and transport recipes, aim to achieve high confinement long pulse ELM-suppressed discharges in KSTAR. Recent advancements include machine learning-based triggering, active probing ELM precursor detection, and ML surrogate model acceleration of GPEC-based edge resonant phasing optimization.

^*This work was supported by the U.S. Department of Energy under DE-FOA-0002702, DE-SC0021968, DE-SC0020372, DE-SC0020357, and DE-SC0021185.

Oct. 7, 2024, 10:30 AM – Oct. 7, 2024, 10:42 AM

Presenters

Dmitriy M Orlov
- University of California, San Diego
- University of California San Diego

Authors

Dmitriy M Orlov
- University of California, San Diego
- University of California San Diego
Nikolas C Logan
- Columbia University
Joseph A Snipes
- Princeton Plasma Physics Laboratory
Egemen Kolemen
- Princeton University
Carlos Alberto Paz-Soldan
- Columbia University
Yueqiang Liu
- General Atomics
Heinke G Frerichs
- University of Wisconsin - Madison
- University of Wisconsin-Madison
Vasilii Khavin
- UC San Diego
Zhihong Lin
- University of California, Irvine
Xishuo Wei
- University of California, Irvine
Yangyang Yu
- University of California, Irvine
Ben Zhu
- Lawrence Livermore Natl Lab
Nils Leuthold
- Columbia University
Priyansh Lunia
- Columbia University
Francesca M Poli
- Princeton Plasma Physics Laboratory
Mario L. Podesta
- Princeton Plasma Physics Laboratory
Qiming Hu
- Princeton Plasma Physics Laboratory
SeongMoo Yang
- Princeton Plasma Physics Laboratory
SangKyeun Kim
- Princeton Plasma Physics Laboratory
- Princeton Plasma Physics Lab
- Princeton Plasma Physics Laboratory (PPPL)
Ricardo Shousha
- PPPL
Cheol-Sik Byun
- Princeton University
Jalal Butt
- Princeton University
Andy Rothstein
- Princeton University
Tyler B Cote
- General Atomics
Shuai Gu
- Oak Ridge Associated Universities
Chen Zhao
- General Atomics
Xuan Sun
- Oak Ridge Associated Universities
Jonathan Morgan Van Blarcum
- University of Wisconsin - Madison
- University of Wisconsin-Madison
Javier H Nicolau
- University of California, San Diego
- San Diego Supercomputer Center
Eric C Howell
- Tech-X Corp
Jong-Kyu Park
- Seoul National University, PPPL
- Seoul National University
Jaemin Seo
- Seoul National University