Evolution of radiation profiles in a strongly baffled divertor on MAST Upgrade

Fabio Federici; Matthew L. Reinke; Bruce Lipschultz; Jack J. Lovell; Kevin Verhaegh; Nicola Lonigro; Cyd Cowley; Mike Kryjak; Peter Ryan; Andrew J. Thornton; James R. Harrison; Byron J. Peterson; Bartosz Lomanowski; Jeremy D. Lore; Yacopo Damizia

doi:10.1016/j.nme.2025.101940

Evolution of radiation profiles in a strongly baffled divertor on MAST Upgrade

Fabio Federici, Matthew L. Reinke, Bruce Lipschultz, Jack J. Lovell, Kevin Verhaegh, Nicola Lonigro, Cyd Cowley, Mike Kryjak, Peter Ryan, Andrew J. Thornton, James R. Harrison, Byron J. Peterson, Bartosz Lomanowski, Jeremy D. Lore, Yacopo Damizia

Power Exhaust and Particle Control

Research output: Contribution to journal › Article › peer-review

Abstract

Plasma detachment in tokamaks is necessary in future tokamaks to sufficiently reduce the heat flux to the target. It involves interactions of the plasma with impurities and neutral particles, leading to significant losses of plasma power, momentum, and particles. An accurate mapping of plasma emissivity in the divertor and X-point region is essential to localise and infer the power losses influencing the detachment process. The recently validated InfraRed Video Bolometer (IRVB) diagnostic, in MAST-U (Federici et al., 2023), enables this mapping with higher spatial resolution than more established methods like resistive bolometers. In previous preliminary work (Federici et al., 2023a), the detachment of the radiation from the target (radiative detachment) was characterised in L-mode (power entering the scrape-off layer, P_SOL∼0.4 MW). With a conventional divertor the inner leg consistently detached ahead of the outer leg, and radiative detachment preceded particle flux detachment. This work presents results also from the third MAST-U experimental campaign, fuelled from the low field side instead of the high field side, including Ohmic and beam heated L-mode shots (with a power exiting the core up to P_SOL∼1–1.5 MW). The radiation peak moves upstream from the target at lower upstream densities than the ion target flux roll-over (typically considered the detachment onset), while radiation on the inner leg detaches before the outer one in high field side fuelled shots and about at the same time in low field side fuelled ones. The movement of the radiation is in partial agreement with the expectations from the DLS model (Myatra, 2021; Cowley et al., 2022; Lipschultz et al., 2016), predicting a sudden shift from the target to the X-point on the inner leg. The energy confinement is found to be related to detachment, but there seems to be some margin between the radiation peak caused by impurity radiation reaching the X-point and confinement being affected, a beneficial characteristic if it could be extrapolated to future reactors. For increasing P_SOL the particle flux roll-over happens for similar upstream densities. Comparing the total radiated power with the D₂ Fulcher band emission evolution shows that in a conventional divertor a significant fraction of the radiated power is due to carbon radiation (outside of the divertor chamber).

Original language	English
Article number	101940
Journal	Nuclear Materials and Energy
Volume	43
DOIs	https://doi.org/10.1016/j.nme.2025.101940
State	Published - Jun 2025

Funding

This work is supported by US Department of Energy, Office of Fusion Energy Sciences under the Spherical Tokamak program, contract DE-AC05-00OR22725 and under the auspices of the EPSRC [EP/L01663X/1]. Support for M. L. Reinke's contributions was in part provided by Commonwealth Fusion Systems. This work has been carried out within the framework of the EUROfusion Consortium, funded by the European Union via the Euratom Research and Training Programme (Grant Agreement No 101052200-EUROfusion) and from the EPSRC [grant number EP/W006839/1]. Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or the European Commission. Neither the European Union nor the European Commission can be held responsible for them. This work is supported by US Department of Energy, Office of Fusion Energy Sciences under the Spherical Tokamak program , contract DE-AC05-00OR22725 and under the auspices of the EPSRC [ EP/L01663X/1 ]. Support for M. L. Reinke’s contributions was in part provided by Commonwealth Fusion Systems. This work has been carried out within the framework of the EUROfusion Consortium, funded by the European Union via the Euratom Research and Training Programme (Grant Agreement No 101052200-EUROfusion ) and from the EPSRC [grant number EP/W006839/1 ]. Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or the European Commission. Neither the European Union nor the European Commission can be held responsible for them.

Keywords

Confinement
DLS model
Detachment
IRVB
Impurity power losses
Radiation detachment
Roll-over

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10.1016/j.nme.2025.101940

Cite this

Federici, F., Reinke, M. L., Lipschultz, B., Lovell, J. J., Verhaegh, K., Lonigro, N., Cowley, C., Kryjak, M., Ryan, P., Thornton, A. J., Harrison, J. R., Peterson, B. J., Lomanowski, B., Lore, J. D., & Damizia, Y. (2025). Evolution of radiation profiles in a strongly baffled divertor on MAST Upgrade. Nuclear Materials and Energy, 43, Article 101940. https://doi.org/10.1016/j.nme.2025.101940

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abstract = "Plasma detachment in tokamaks is necessary in future tokamaks to sufficiently reduce the heat flux to the target. It involves interactions of the plasma with impurities and neutral particles, leading to significant losses of plasma power, momentum, and particles. An accurate mapping of plasma emissivity in the divertor and X-point region is essential to localise and infer the power losses influencing the detachment process. The recently validated InfraRed Video Bolometer (IRVB) diagnostic, in MAST-U (Federici et al., 2023), enables this mapping with higher spatial resolution than more established methods like resistive bolometers. In previous preliminary work (Federici et al., 2023a), the detachment of the radiation from the target (radiative detachment) was characterised in L-mode (power entering the scrape-off layer, PSOL∼0.4 MW). With a conventional divertor the inner leg consistently detached ahead of the outer leg, and radiative detachment preceded particle flux detachment. This work presents results also from the third MAST-U experimental campaign, fuelled from the low field side instead of the high field side, including Ohmic and beam heated L-mode shots (with a power exiting the core up to PSOL∼1–1.5 MW). The radiation peak moves upstream from the target at lower upstream densities than the ion target flux roll-over (typically considered the detachment onset), while radiation on the inner leg detaches before the outer one in high field side fuelled shots and about at the same time in low field side fuelled ones. The movement of the radiation is in partial agreement with the expectations from the DLS model (Myatra, 2021; Cowley et al., 2022; Lipschultz et al., 2016), predicting a sudden shift from the target to the X-point on the inner leg. The energy confinement is found to be related to detachment, but there seems to be some margin between the radiation peak caused by impurity radiation reaching the X-point and confinement being affected, a beneficial characteristic if it could be extrapolated to future reactors. For increasing PSOL the particle flux roll-over happens for similar upstream densities. Comparing the total radiated power with the D2 Fulcher band emission evolution shows that in a conventional divertor a significant fraction of the radiated power is due to carbon radiation (outside of the divertor chamber).",

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AU - Federici, Fabio

AU - Reinke, Matthew L.

AU - Lipschultz, Bruce

AU - Lovell, Jack J.

AU - Verhaegh, Kevin

AU - Lonigro, Nicola

AU - Cowley, Cyd

AU - Kryjak, Mike

AU - Ryan, Peter

AU - Thornton, Andrew J.

AU - Harrison, James R.

AU - Peterson, Byron J.

AU - Lomanowski, Bartosz

AU - Lore, Jeremy D.

AU - Damizia, Yacopo

PY - 2025/6

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AB - Plasma detachment in tokamaks is necessary in future tokamaks to sufficiently reduce the heat flux to the target. It involves interactions of the plasma with impurities and neutral particles, leading to significant losses of plasma power, momentum, and particles. An accurate mapping of plasma emissivity in the divertor and X-point region is essential to localise and infer the power losses influencing the detachment process. The recently validated InfraRed Video Bolometer (IRVB) diagnostic, in MAST-U (Federici et al., 2023), enables this mapping with higher spatial resolution than more established methods like resistive bolometers. In previous preliminary work (Federici et al., 2023a), the detachment of the radiation from the target (radiative detachment) was characterised in L-mode (power entering the scrape-off layer, PSOL∼0.4 MW). With a conventional divertor the inner leg consistently detached ahead of the outer leg, and radiative detachment preceded particle flux detachment. This work presents results also from the third MAST-U experimental campaign, fuelled from the low field side instead of the high field side, including Ohmic and beam heated L-mode shots (with a power exiting the core up to PSOL∼1–1.5 MW). The radiation peak moves upstream from the target at lower upstream densities than the ion target flux roll-over (typically considered the detachment onset), while radiation on the inner leg detaches before the outer one in high field side fuelled shots and about at the same time in low field side fuelled ones. The movement of the radiation is in partial agreement with the expectations from the DLS model (Myatra, 2021; Cowley et al., 2022; Lipschultz et al., 2016), predicting a sudden shift from the target to the X-point on the inner leg. The energy confinement is found to be related to detachment, but there seems to be some margin between the radiation peak caused by impurity radiation reaching the X-point and confinement being affected, a beneficial characteristic if it could be extrapolated to future reactors. For increasing PSOL the particle flux roll-over happens for similar upstream densities. Comparing the total radiated power with the D2 Fulcher band emission evolution shows that in a conventional divertor a significant fraction of the radiated power is due to carbon radiation (outside of the divertor chamber).

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Evolution of radiation profiles in a strongly baffled divertor on MAST Upgrade

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