Demonstration of Super-X divertor exhaust control for transient heat load management in compact fusion reactors

The EUROfusion Tokamak Exploitation Team; the MAST-U team

doi:10.1038/s41560-025-01824-7

Demonstration of Super-X divertor exhaust control for transient heat load management in compact fusion reactors

The EUROfusion Tokamak Exploitation Team
, the MAST-U team

FOM Institute DIFFER 'Dutch Institute for Fundamental Energy Research'
Technical University of Eindhoven
Culham Science Centre
University of York
Oak Ridge National Laboratory
Max-Planck-Institut für Plasmaphysik
ENAC-IIC-GEL
University of Liverpool
National Centre for Nuclear Research
University of Padova
IRFM-CEA Centre de Cadarache
University of Rome
Department of Biochemistry and Molecular and Structural Biology
Research Centre Julich
National Technical University of Athens
Dip.to Fusione e Tecnologie per la Sicurezza Nucleare
Aix-Marseille Université
University of Helsinki
Institute of Plasma Physics AS CR
KTH Royal Institute of Technology
Institute of Nuclear Research, National Academy of Sciences in Ukraine
Chalmers University of Technology
University of Rome “Tor Vergata”
Warsaw University of Technology
Technical University of Denmark
Institute of Plasma Physics and Laser Microfusion
Kharkov National University
ITER
Durham University
Laboratorio Nacional de Fusión
Plasma and Radiation Physics (INFLPR)
Consorzio CREATE
University of Seville
Instituto Superior Técnico
Ev-K2-CNR Committee
Ghent University
Centre for Energy Research
Aalto University
Universidad Carlos III de Madrid
Plasma Science and Fusion Center
Koninklijke Militaire School - Ecole Royale Militaire
University of California, San Diego
Politecnico di Milano
Institute for Plasma Science and Technology
VTT Technical Research Centre of Finland Ltd
Politecnico di Torino
Lithuanian Energy Institute
Kharkov Institute of Physics and Technology
Universitá di Cagliari
University of Innsbruck
University Roma Tre
University of Oxford
Heinrich Heine University Düsseldorf
EUROfusion Programme Management Unit
IUSTI
KU Leuven
Tuscia University
Vienna University of Technology
University of Milano-Bicocca
Graz University of Technology
Earth Sciences
Loughborough University
Institute for Nuclear Physics
Institute of Electronics Bulgarian Academy of Sciences
Aristotle University of Thessaloniki
Uppsala University
Univ.́ Henri Poincaré
Aix Marseille Université
Queen's University of Belfast
Università degli Studi di Catania
Columbia University
University of California, Los Angeles
General Atomics
University of Strathclyde
Lawrence Livermore National Laboratory
Long Beach VA and University of California
ENEA Climate Modeling and Impacts
Consorzio Rfx
College of William and Mary
University of Warwick
The University of Texas at Austin
ASTAR
CEA Cadarache
Dublin City University
University of Manchester
Florida International University
Princeton Plasma Physics Laboratory
Astrodel LLC
Imperial College London
University of Tromsø - The Arctic University of Norway

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Nuclear fusion could offer clean, abundant energy. However, managing the power exhausted from the core fusion plasma towards the reactor wall remains a major challenge. This is compounded in emerging compact reactor designs promising more cost-effective pathways towards commercial fusion energy. Alternative Divertor Configurations (ADCs) are a potential solution. In this work, we demonstrate exhaust control in ADCs, employing a novel method to diagnose the neutral gas buffer, which shields the target. Our work on the Mega Ampere Spherical Tokamak Upgrade shows that ADCs tackle key risks and uncertainties for fusion energy. Their highly reduced sensitivity to perturbations enables active exhaust control in otherwise unfeasible situations and facilitates an increased passive absorption of transients, which would otherwise damage the divertor. We observe a strong decoupling of each divertor from other reactor regions, enabling near-independent control of the divertors and core plasma. Our work showcases the real-world benefits of ADCs for effective heat load management in fusion power reactors.

langue originale	Anglais
Pages (de - à)	1116-1131
Nombre de pages	16
journal	Nature Energy
Volume	10
Numéro de publication	9
Les DOIs	https://doi.org/10.1038/s41560-025-01824-7
état	Publié - 1 sept. 2025

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title = "Demonstration of Super-X divertor exhaust control for transient heat load management in compact fusion reactors",

abstract = "Nuclear fusion could offer clean, abundant energy. However, managing the power exhausted from the core fusion plasma towards the reactor wall remains a major challenge. This is compounded in emerging compact reactor designs promising more cost-effective pathways towards commercial fusion energy. Alternative Divertor Configurations (ADCs) are a potential solution. In this work, we demonstrate exhaust control in ADCs, employing a novel method to diagnose the neutral gas buffer, which shields the target. Our work on the Mega Ampere Spherical Tokamak Upgrade shows that ADCs tackle key risks and uncertainties for fusion energy. Their highly reduced sensitivity to perturbations enables active exhaust control in otherwise unfeasible situations and facilitates an increased passive absorption of transients, which would otherwise damage the divertor. We observe a strong decoupling of each divertor from other reactor regions, enabling near-independent control of the divertors and core plasma. Our work showcases the real-world benefits of ADCs for effective heat load management in fusion power reactors.",

author = "\{The EUROfusion Tokamak Exploitation Team\} and \{the MAST-U team\} and B. Kool and K. Verhaegh and Derks, \{G. L.\} and Wijkamp, \{T. A.\} and Koenders, \{J. T.W.\} and N. Lonigro and G. McArdle and C. Vincent and J. Lovell and Henderson, \{S. S.\} and F. Federici and D. Brida and H. Reimerdes and N. Osborne and \{van Berkel\}, M. and I. Zychor and M. Zurita and M. Zuin and X. Zou and Zotta, \{V. K.\} and A. Zohar and M. Zlobinski and Zimmermann, \{C. F.B.\} and P. Zestanakis and M. Zerbini and J. Zebrowski and Y. Zayachuk and D. Zarzoso and P. Zanca and L. Zakharov and G. Zadvitskiy and B. Zaar and R. Yi and V. Yanovskiy and H. Yang and Y. Yakovenko and D. Yadykin and S. Xu and L. Xiang and I. Wyss and C. Wuethrich and A. Wojenski and M. Wischmeier and T. Wilson and M. Willensdorfer and T. Wijkamp and M. Wiesenberger and S. Wiesen and L. Vermare and P. Hennequin",

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doi = "10.1038/s41560-025-01824-7",

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AU - The EUROfusion Tokamak Exploitation Team

AU - the MAST-U team

AU - Kool, B.

AU - Verhaegh, K.

AU - Derks, G. L.

AU - Wijkamp, T. A.

AU - Koenders, J. T.W.

AU - Lonigro, N.

AU - McArdle, G.

AU - Vincent, C.

AU - Lovell, J.

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AU - Federici, F.

AU - Brida, D.

AU - Reimerdes, H.

AU - Osborne, N.

AU - van Berkel, M.

AU - Zychor, I.

AU - Zurita, M.

AU - Zuin, M.

AU - Zou, X.

AU - Zotta, V. K.

AU - Zohar, A.

AU - Zlobinski, M.

AU - Zimmermann, C. F.B.

AU - Zestanakis, P.

AU - Zerbini, M.

AU - Zebrowski, J.

AU - Zayachuk, Y.

AU - Zarzoso, D.

AU - Zanca, P.

AU - Zakharov, L.

AU - Zadvitskiy, G.

AU - Zaar, B.

AU - Yi, R.

AU - Yanovskiy, V.

AU - Yang, H.

AU - Yakovenko, Y.

AU - Yadykin, D.

AU - Xu, S.

AU - Xiang, L.

AU - Wyss, I.

AU - Wuethrich, C.

AU - Wojenski, A.

AU - Wischmeier, M.

AU - Wilson, T.

AU - Willensdorfer, M.

AU - Wijkamp, T.

AU - Wiesenberger, M.

AU - Wiesen, S.

AU - Vermare, L.

AU - Hennequin, P.

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N2 - Nuclear fusion could offer clean, abundant energy. However, managing the power exhausted from the core fusion plasma towards the reactor wall remains a major challenge. This is compounded in emerging compact reactor designs promising more cost-effective pathways towards commercial fusion energy. Alternative Divertor Configurations (ADCs) are a potential solution. In this work, we demonstrate exhaust control in ADCs, employing a novel method to diagnose the neutral gas buffer, which shields the target. Our work on the Mega Ampere Spherical Tokamak Upgrade shows that ADCs tackle key risks and uncertainties for fusion energy. Their highly reduced sensitivity to perturbations enables active exhaust control in otherwise unfeasible situations and facilitates an increased passive absorption of transients, which would otherwise damage the divertor. We observe a strong decoupling of each divertor from other reactor regions, enabling near-independent control of the divertors and core plasma. Our work showcases the real-world benefits of ADCs for effective heat load management in fusion power reactors.

AB - Nuclear fusion could offer clean, abundant energy. However, managing the power exhausted from the core fusion plasma towards the reactor wall remains a major challenge. This is compounded in emerging compact reactor designs promising more cost-effective pathways towards commercial fusion energy. Alternative Divertor Configurations (ADCs) are a potential solution. In this work, we demonstrate exhaust control in ADCs, employing a novel method to diagnose the neutral gas buffer, which shields the target. Our work on the Mega Ampere Spherical Tokamak Upgrade shows that ADCs tackle key risks and uncertainties for fusion energy. Their highly reduced sensitivity to perturbations enables active exhaust control in otherwise unfeasible situations and facilitates an increased passive absorption of transients, which would otherwise damage the divertor. We observe a strong decoupling of each divertor from other reactor regions, enabling near-independent control of the divertors and core plasma. Our work showcases the real-world benefits of ADCs for effective heat load management in fusion power reactors.

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DO - 10.1038/s41560-025-01824-7

M3 - Article

AN - SCOPUS:105016793617

SN - 2058-7546

VL - 10

SP - 1116

EP - 1131

JO - Nature Energy

JF - Nature Energy

IS - 9

ER -

Demonstration of Super-X divertor exhaust control for transient heat load management in compact fusion reactors

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