TY - JOUR
T1 - Disruption prediction with artificial intelligence techniques in tokamak plasmas
AU - JET Contributors
AU - Vega, J.
AU - Murari, A.
AU - Dormido-Canto, S.
AU - Rattá, G. A.
AU - Gelfusa, M.
AU - Mailloux, J.
AU - Abid, N.
AU - Abraham, K.
AU - Abreu, P.
AU - Adabonyan, O.
AU - Adrich, P.
AU - Afanasev, V.
AU - Afzal, M.
AU - Ahlgren, T.
AU - Aho-Mantila, L.
AU - Aiba, N.
AU - Airila, M.
AU - Akhtar, M.
AU - Albanese, R.
AU - Alderson-Martin, M.
AU - Alegre, D.
AU - Aleiferis, S.
AU - Aleksa, A.
AU - Alekseev, A. G.
AU - Alessi, E.
AU - Aleynikov, P.
AU - Algualcil, J.
AU - Ali, M.
AU - Allinson, M.
AU - Alper, B.
AU - Alves, E.
AU - Ambrosino, G.
AU - Ambrosino, R.
AU - Amosov, V.
AU - Sundén, E. Andersson
AU - Buermans, J.
AU - Crombé, K.
AU - Dumortier, P.
AU - Durodié, F.
AU - Jachmich, S.
AU - Kazakov, Y. E.O.
AU - Krivska, A.
AU - Lerche, E.
AU - Lyssoivan, A.
AU - Messiaen, A.
AU - Moradi, S.
AU - Ongena, J.
AU - Eester, D. Van
AU - Verdoolaege, G.
AU - Wauters, T.
N1 - Publisher Copyright:
© 2022, Springer Nature Limited.
PY - 2022/7/1
Y1 - 2022/7/1
N2 - In nuclear fusion reactors, plasmas are heated to very high temperatures of more than 100 million kelvin and, in so-called tokamaks, they are confined by magnetic fields in the shape of a torus. Light nuclei, such as deuterium and tritium, undergo a fusion reaction that releases energy, making fusion a promising option for a sustainable and clean energy source. Tokamak plasmas, however, are prone to disruptions as a result of a sudden collapse of the system terminating the fusion reactions. As disruptions lead to an abrupt loss of confinement, they can cause irreversible damage to present-day fusion devices and are expected to have a more devastating effect in future devices. Disruptions expected in the next-generation tokamak, ITER, for example, could cause electromagnetic forces larger than the weight of an Airbus A380. Furthermore, the thermal loads in such an event could exceed the melting threshold of the most resistant state-of-the-art materials by more than an order of magnitude. To prevent disruptions or at least mitigate their detrimental effects, empirical models obtained with artificial intelligence methods, of which an overview is given here, are commonly employed to predict their occurrence—and ideally give enough time to introduce counteracting measures.
AB - In nuclear fusion reactors, plasmas are heated to very high temperatures of more than 100 million kelvin and, in so-called tokamaks, they are confined by magnetic fields in the shape of a torus. Light nuclei, such as deuterium and tritium, undergo a fusion reaction that releases energy, making fusion a promising option for a sustainable and clean energy source. Tokamak plasmas, however, are prone to disruptions as a result of a sudden collapse of the system terminating the fusion reactions. As disruptions lead to an abrupt loss of confinement, they can cause irreversible damage to present-day fusion devices and are expected to have a more devastating effect in future devices. Disruptions expected in the next-generation tokamak, ITER, for example, could cause electromagnetic forces larger than the weight of an Airbus A380. Furthermore, the thermal loads in such an event could exceed the melting threshold of the most resistant state-of-the-art materials by more than an order of magnitude. To prevent disruptions or at least mitigate their detrimental effects, empirical models obtained with artificial intelligence methods, of which an overview is given here, are commonly employed to predict their occurrence—and ideally give enough time to introduce counteracting measures.
UR - http://www.scopus.com/inward/record.url?scp=85133819618&partnerID=8YFLogxK
U2 - 10.1038/s41567-022-01602-2
DO - 10.1038/s41567-022-01602-2
M3 - Article
AN - SCOPUS:85133819618
SN - 1745-2473
VL - 18
SP - 741
EP - 750
JO - Nature Physics
JF - Nature Physics
IS - 7
ER -