Predictive modeling of NSTX discharges with the updated multi-mode anomalous transport module

Rafiq, T.; Wilson, C.; Clauser, C.; Schuster, E.; Weiland, J.; Anderson, J.; Kaye, S. M.; Pankin, A.; LeBlanc, B. P.; Bell, R. E.

doi:10.1088/1741-4326/ad4d01

Title: Predictive modeling of NSTX discharges with the updated multi-mode anomalous transport module

Journal Article · 02 June 2024 · Nuclear Fusion

DOI: https://doi.org/10.1088/1741-4326/ad4d01 · OSTI ID:2369881

;

; Pankin, A.; LeBlanc, B. P.;

Abstract The objective of this study is twofold: firstly, to demonstrate the consistency between the anomalous transport results produced by updated Multi-Mode Model (MMM) version 9.0.4 and those obtained through gyrokinetic simulations; and secondly, to showcase MMM’s ability to predict electron and ion temperature profiles in low aspect ratio, high beta NSTX discharges. MMM encompasses a range of transport mechanisms driven by electron and ion temperature gradients, trapped electrons, kinetic ballooning, peeling, microtearing, and drift resistive inertial ballooning modes. These modes within MMM are being verified through corresponding gyrokinetic results. The modes that potentially contribute to ion thermal transport are stable in MMM, aligning with both experimental data and findings from linear CGYRO simulations. The isotope effects on these modes are also studied and higher mass is found to be stabilizing, consistent with the experimental trend. The electron thermal power across the flux surface is computed within MMM and compared to experimental measurements and nonlinear CGYRO simulation results. Specifically, the electron temperature gradient modes (ETGM) within MMM account for 2.0 MW of thermal power, consistent with experimental findings. It is noteworthy that the ETGM model requires approximately 5.0 ms of computation time on a standard desktop, while nonlinear CGYRO simulations necessitate 8.0 h on 8 K cores. MMM proves to be highly computationally efficient, a crucial attribute for various applications, including real-time control, tokamak scenario optimization, and uncertainty quantification of experimental data.

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Sponsoring Organization:: USDOE

Grant/Contract Number:: SC0013977

OSTI ID:: 2369881

Alternate ID(s):: OSTI ID: 2352329; OSTI ID: 2371826; OSTI ID: 2376999

Journal Information:: Nuclear Fusion, Journal Name: Nuclear Fusion Journal Issue: 7 Vol. 64; ISSN 0029-5515

Publisher:: IOP PublishingCopyright Statement

Country of Publication:: IAEA

Language:: English

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