@article{9188,
  author = {I. Bandyopadhyay and V. Igochine and O. Sauter and S.A. Sabbagh and J.K. Park and E. Nardon and F. Villone and M. Maraschek and G. Pautasso and M.R. de Baar and N. Eidietis and S.C. Jardin and D.A. Humphreys and M. Dubrov and F.J. Artola and L. Bardoczi and L.R. Baylor and J. Berkery and A.H. Boozer and B. Cannas and Z . Y. Chen and B. Esposito and A. Fanni and N.M. Ferraro and R. Fitzpatrick and S. Gerasimov and T. Goodman and J. Graves and P. Maget and et al. and Disruption and Control Topical Group ITPA MHD},
  title = {MHD, disruptions and control physics: Chapter 4 of the special issue: on the path to tokamak burning plasma operation},
  abstract = {In this chapter, we review the progress in MHD stability, disruptions and control in magnetic fusion research that has occurred over the past (more than) one and a half decades since the publication by Hender et al in 2007 on the same topic as part of the update of ITER Physics Basis. During this period, remarkable progress has been achieved in the understanding of the basic physics and overall control of MHD instabilities through a wide spectrum of dedicated experiments, theory and modeling. The sawtooth activities are probably today one of the best understood of MHD events and very robust control schemes have been developed for reliable operation of tokamaks through core heating. Similarly, significant improvements have been achieved in understanding and control of neoclassical tearing modes, resistive wall modes or locked modes and their control through ECCD or error field control. The field of disruption prediction through application of artificial intelligence, machine learning or deep learning methods, which had already started at the time of the 2007 review, has progressed significantly due to general progress in these fields and application of newer, more sophisticated algorithms. However, although remarkable progress has been achieved in the field of Disruptions, their understanding, prediction, possible avoidance and mitigation still remain probably the most active fields of R&D globally in this field. This is especially because reactor grade machines like ITER and DEMO will be much less tolerant in respect of disruptions and runaway currents, and their occurrences must be either avoided altogether or minimized to an acceptable value without causing any significant hindrance to robust machine operations. This review is intended to present a broad spectrum of the R&D that has occurred in this field in support of ITER, which will also be of immense significance for all future machines, especially reactors like DEMO.},
  year = {2025},
  journal = {Nuclear Fusion},
  volume = {65},
  pages = {103001},
  doi = {10.1088/1741-4326/ade7a0},
  language = {eng},
}