First SOLPS‐ITER simulations of ASDEX Upgrade partially detached H‐mode with boron impurity : the missing radiation at the outer strike‐point region

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Makarov, S. O. and Coster, D. P. and Gleiter, T. and Brida, D. and Muraca, M. and Dux, R. and David, P. and Kurzan, B. and Bonnin, X. and O'Mullane, M., ASDEX Upgrade team (2024) First SOLPS‐ITER simulations of ASDEX Upgrade partially detached H‐mode with boron impurity : the missing radiation at the outer strike‐point region. Contributions to Plasma Physics, 64 (7-8). e202300139. ISSN 1521-3986 (https://doi.org/10.1002/ctpp.202300139)

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Abstract

Partially detached H‐modes are the baseline regime for the future ITER operation. The ASDEX Upgrade partially detached H‐mode is modeled using the SOLPS‐ITER code with drifts enabled and compared with experimental data. For the first time, boron (B) impurity is simulated in the Scrape‐off layer (SOL) and divertor. A comparison between divertor diagnostics and discrepancies between Langmuir probe and Divertor Thomson scattering/Stark broadening diagnostic are discussed. In the modeling, experimental target profiles are reproduced if the experimental level of radiation in the SOL and divertor is achieved using nitrogen (N) impurity seeding. Bolometry measurements detect substantial radiation from the partially detached outer strike point. With B radiation, this maximum in bolometry data is reproduced in the modeling, which is not possible with N alone.

ORCID iDs

Makarov, S. O., Coster, D. P., Gleiter, T., Brida, D., Muraca, M., Dux, R., David, P., Kurzan, B., Bonnin, X. and O'Mullane, M. ORCID logoORCID: https://orcid.org/0000-0002-2160-4546;
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