Experimental research on the TCV tokamak

B. P. Duval; A. Abdolmaleki; M. Agostini; C. J. Ajay; S. Alberti; E. Alessi; G. Anastasiou; Y. Andrèbe; G. M. Apruzzese; F. Auriemma; J. Ayllon-Guerola; F. Bagnato; A. Baillod; F. Bairaktaris; L. Balbinot; A. Balestri; M. Baquero-Ruiz; C. Barcellona; M. Bernert; W. Bin; P. Blanchard; J. Boedo; T. Bolzonella; F. Bombarda; L. Boncagni; M. Bonotto; T. O.S.J. Bosman; D. Brida; D. Brunetti; J. Buchli; J. Buerman; P. Buratti; A. Burckhart; D. Busil; J. Caloud; Y. Camenen; A. Cardinali; S. Carli; D. Carnevale; F. Carpanese; M. Carpita; C. Castaldo; F. Causa; J. Cavalier; M. Cavedon; J. A. Cazabonne; J. Cerovsky; B. Chapman; M. Chernyshova; P. Chmielewski; A. Chomiczewska; G. Ciraolo; S. Coda; C. Colandrea; C. Contré; R. Coosemans; L. Cordaro; S. Costea; T. Craciunescu; K. Crombe; A. Dal Molin; O. D’Arcangelo; D. de Las Casas; J. Decker; J. Degrave; H. de Oliveira; G. L. Derks; L. E. di Grazia; C. Donner; M. Dreval; M. G. Dunne; G. Durr-Legoupil-Nicoud; B. Esposito; T. Ewalds; M. Faitsch; M. Farník; A. Fasoli; F. Felici; J. Ferreira; O. Février; O. Ficker; A. Frank; E. Fransson; L. Frassinetti; L. Fritz; I. Furno; D. Galassi; K. Gałązka; J. Galdon-Quiroga; S. Galeani; C. Galperti; S. Garavaglia; M. Garcia-Munoz; P. Gaudio; M. Gelfusa; J. Genoud; R. Gerrú Miguelanez; G. Ghillardi; M. Giacomin; L. Gil; A. Gillgren; C. Giroud; T. Golfinopoulos; T. Goodman; G. Gorini; S. Gorno; G. Grenfell; M. Griener; M. Gruca; T. Gyergyek; R. Hafner; M. Hamed; D. Hamm; W. Han; G. Harrer; J. R. Harrison; D. Hassabis; S. Henderson; P. Hennequin; J. Hidalgo-Salaverri; J. P. Hogge; M. Hoppe; J. Horacek; A. Huber; E. Huett; A. Iantchenko; P. Innocente; C. Ionita-Schrittwieser; I. Ivanova Stanik; M. Jablczynska; A. Jansen van Vuuren; A. Jardin; H. Järleblad; A. E. Järvinen; J. Kalis; R. Karimov; A. N. Karpushov; K. Kavukcuoglu; J. Kay; Y. Kazakov; J. Keeling; A. Kirjasuo; J. T.W. Koenders; P. Kohli; M. Komm; M. Kong; J. Kovacic; E. Kowalska-Strzeciwilk; O. Krutkin; O. Kudlacek; U. Kumar; R. Kwiatkowski; B. Labit; L. Laguardia; E. Laszynska; A. Lazaros; K. Lee; E. Lerche; B. Linehan; D. Liuzza; T. Lunt; E. Macusova; D. Mancini; P. Mantica; M. Maraschek; G. Marceca; S. Marchioni; A. Mariani; M. Marin; A. Marinoni; L. Martellucci; Y. Martin; P. Martin; L. Martinelli; F. Martinelli; J. R. Martin-Solis; S. Masillo; R. Masocco; V. Masson; A. Mathews; M. Mattei; D. Mazon; S. Mazzi; S. Mazzi; S. Y. Medvedev; C. Meineri; A. Mele; V. Menkovski; A. Merle; H. Meyer; K. Mikszuta-Michalik; I. G. Miron; P. A. Molina Cabrera; A. Moro; A. Murari; P. Muscente; D. Mykytchuk; F. Nabais; F. Napoli; R. D. Nem; M. Neunert; S. K. Nielsen; A. Nielsen; M. Nocente; S. Noury; S. Nowak; H. Nyström; N. Offeddu; S. Olasz; F. Oliva; D. S. Oliveira; F. P. Orsitto; N. Osborne; P. Oyola Dominguez; O. Pan; E. Panontin; A. D. Papadopoulos; P. Papagiannis; G. Papp; M. Passoni; F. Pastore; A. Pau; R. O. Pavlichenko; A. C. Pedersen; M. Pedrini; G. Pelka; E. Peluso; A. Perek; C. Perez Von Thun; F. Pesamosca; D. Pfau; V. Piergotti; L. Pigatto; C. Piron; L. Piron; A. Pironti; U. Plank; V. Plyusnin; Y. R.J. Poels; G. I. Pokol; J. Poley-Sanjuan; M. Poradzinski; L. Porte; C. Possieri; A. Poulsen; M. J. Pueschel; T. Pütterich; V. Quadri; M. Rabinski; R. Ragona; H. Raj; A. Redl; H. Reimerdes; C. Reux; D. Ricci; M. Riedmiller; S. Rienäcker; D. Rigamonti; N. Rispoli; J. F. Rivero-Rodriguez; C. F.Romero Madrid; J. Rueda Rueda; P. J. Ryan; M. Salewski; A. Salmi; M. Sassano; O. Sauter; N. Schoonheere; R. W. Schrittwieser; F. Sciortino; A. Selce; L. Senni; S. Sharapov; U. A. Sheikh; B. Sieglin; M. Silva; D. Silvagni; B. Simmendefeldt Schmidt; L. Simons; E. R. Solano; C. Sozzi; M. Spolaore; L. Spolladore; A. Stagni; P. Strand; G. Sun; W. Suttrop; J. Svoboda; B. Tal; T. Tala; P. Tamain; M. Tardocchi; A. Tema Biwole; A. Tenaglia; D. Terranova; D. Testa; C. Theiler; A. Thornton; A. S. Thrysoe; M. Tomes; E. Tonello; H. Torreblanca; B. Tracey; M. Tsimpoukelli; C. Tsironis; C. K. Tsui; M. Ugoletti; M. Vallar; M. van Berkel; S. van Mulders; M. van Rossem; C. Venturini; M. Veranda; T. Verdier; K. Verhaegh; L. Vermare; N. Vianello; E. Viezzer; F. Villone; B. Vincent; P. Vincenzi; I. Voitsekhovitch; L. Votta; N. M.T. Vu; Y. Wang; E. Wang; T. Wauters; M. Weiland; H. Weisen; N. Wendler; S. Wiesen; M. Wiesenberger; T. Wijkamp; C. Wüthrich; D. Yadykin; H. Yang; V. Yanovskiy; J. Zebrowski; P. Zestanakis; M. Zuin; M. Zurita

doi:10.1088/1741-4326/ad8361

Experimental research on the TCV tokamak

B. P. Duval
, A. Abdolmaleki
, M. Agostini
, C. J. Ajay
, S. Alberti
, E. Alessi
, G. Anastasiou
, Y. Andrèbe
, G. M. Apruzzese
, F. Auriemma
, J. Ayllon-Guerola
, F. Bagnato
, A. Baillod
, F. Bairaktaris
, L. Balbinot
, A. Balestri
, M. Baquero-Ruiz
, C. Barcellona
, M. Bernert
, W. Bin

P. Blanchard, J. Boedo, T. Bolzonella, F. Bombarda, L. Boncagni, M. Bonotto, T. O.S.J. Bosman, D. Brida, D. Brunetti, J. Buchli, J. Buerman, P. Buratti, A. Burckhart, D. Busil, J. Caloud, Y. Camenen, A. Cardinali, S. Carli, D. Carnevale, F. Carpanese, M. Carpita, C. Castaldo, F. Causa, J. Cavalier, M. Cavedon, J. A. Cazabonne, J. Cerovsky, B. Chapman, M. Chernyshova, P. Chmielewski, A. Chomiczewska, G. Ciraolo, S. Coda, C. Colandrea, C. Contré, R. Coosemans, L. Cordaro, S. Costea, T. Craciunescu, K. Crombe, A. Dal Molin, O. D’Arcangelo, D. de Las Casas, J. Decker, J. Degrave, H. de Oliveira, G. L. Derks, L. E. di Grazia, C. Donner, M. Dreval, M. G. Dunne, G. Durr-Legoupil-Nicoud, B. Esposito, T. Ewalds, M. Faitsch, M. Farník, A. Fasoli, F. Felici, J. Ferreira, O. Février, O. Ficker, A. Frank, E. Fransson, L. Frassinetti, L. Fritz, I. Furno, D. Galassi, K. Gałązka, J. Galdon-Quiroga, S. Galeani, C. Galperti, S. Garavaglia, M. Garcia-Munoz, P. Gaudio, M. Gelfusa, J. Genoud, R. Gerrú Miguelanez, G. Ghillardi, M. Giacomin, L. Gil, A. Gillgren, C. Giroud, T. Golfinopoulos, T. Goodman, G. Gorini, S. Gorno, G. Grenfell, M. Griener, M. Gruca, T. Gyergyek, R. Hafner, M. Hamed, D. Hamm, W. Han, G. Harrer, J. R. Harrison, D. Hassabis, S. Henderson, P. Hennequin, J. Hidalgo-Salaverri, J. P. Hogge, M. Hoppe, J. Horacek, A. Huber, E. Huett, A. Iantchenko, P. Innocente, C. Ionita-Schrittwieser, I. Ivanova Stanik, M. Jablczynska, A. Jansen van Vuuren, A. Jardin, H. Järleblad, A. E. Järvinen, J. Kalis, R. Karimov, A. N. Karpushov, K. Kavukcuoglu, J. Kay, Y. Kazakov, J. Keeling, A. Kirjasuo, J. T.W. Koenders, P. Kohli, M. Komm, M. Kong, J. Kovacic, E. Kowalska-Strzeciwilk, O. Krutkin, O. Kudlacek, U. Kumar, R. Kwiatkowski, B. Labit, L. Laguardia, E. Laszynska, A. Lazaros, K. Lee, E. Lerche, B. Linehan, D. Liuzza, T. Lunt, E. Macusova, D. Mancini, P. Mantica, M. Maraschek, G. Marceca, S. Marchioni, A. Mariani, M. Marin, A. Marinoni, L. Martellucci, Y. Martin, P. Martin, L. Martinelli, F. Martinelli, J. R. Martin-Solis, S. Masillo, R. Masocco, V. Masson, A. Mathews, M. Mattei, D. Mazon, S. Mazzi, S. Mazzi, S. Y. Medvedev, C. Meineri, A. Mele, V. Menkovski, A. Merle, H. Meyer, K. Mikszuta-Michalik, I. G. Miron, P. A. Molina Cabrera, A. Moro, A. Murari, P. Muscente, D. Mykytchuk, F. Nabais, F. Napoli, R. D. Nem, M. Neunert, S. K. Nielsen, A. Nielsen, M. Nocente, S. Noury, S. Nowak, H. Nyström, N. Offeddu, S. Olasz, F. Oliva, D. S. Oliveira, F. P. Orsitto, N. Osborne, P. Oyola Dominguez, O. Pan, E. Panontin, A. D. Papadopoulos, P. Papagiannis, G. Papp, M. Passoni, F. Pastore, A. Pau, R. O. Pavlichenko, A. C. Pedersen, M. Pedrini, G. Pelka, E. Peluso, A. Perek, C. Perez Von Thun, F. Pesamosca, D. Pfau, V. Piergotti, L. Pigatto, C. Piron, L. Piron, A. Pironti, U. Plank, V. Plyusnin, Y. R.J. Poels, G. I. Pokol, J. Poley-Sanjuan, M. Poradzinski, L. Porte, C. Possieri, A. Poulsen, M. J. Pueschel, T. Pütterich, V. Quadri, M. Rabinski, R. Ragona, H. Raj, A. Redl, H. Reimerdes, C. Reux, D. Ricci, M. Riedmiller, S. Rienäcker, D. Rigamonti, N. Rispoli, J. F. Rivero-Rodriguez, C. F.Romero Madrid, J. Rueda Rueda, P. J. Ryan, M. Salewski, A. Salmi, M. Sassano, O. Sauter, N. Schoonheere, R. W. Schrittwieser, F. Sciortino, A. Selce, L. Senni, S. Sharapov, U. A. Sheikh, B. Sieglin, M. Silva, D. Silvagni, B. Simmendefeldt Schmidt, L. Simons, E. R. Solano, C. Sozzi, M. Spolaore, L. Spolladore, A. Stagni, P. Strand, G. Sun, W. Suttrop, J. Svoboda, B. Tal, T. Tala, P. Tamain, M. Tardocchi, A. Tema Biwole, A. Tenaglia, D. Terranova, D. Testa, C. Theiler, A. Thornton, A. S. Thrysoe, M. Tomes, E. Tonello, H. Torreblanca, B. Tracey, M. Tsimpoukelli, C. Tsironis, C. K. Tsui, M. Ugoletti, M. Vallar, M. van Berkel, S. van Mulders, M. van Rossem, C. Venturini, M. Veranda, T. Verdier, K. Verhaegh, L. Vermare, N. Vianello, E. Viezzer, F. Villone, B. Vincent, P. Vincenzi, I. Voitsekhovitch, L. Votta, N. M.T. Vu, Y. Wang, E. Wang, T. Wauters, M. Weiland, H. Weisen, N. Wendler, S. Wiesen, M. Wiesenberger, T. Wijkamp, C. Wüthrich, D. Yadykin, H. Yang, V. Yanovskiy, J. Zebrowski, P. Zestanakis, M. Zuin, M. Zurita

Laboratory for Plasma Physics

Ecole Polytechnique Federale de Lausanne
Google DeepMind
Consorzio Rfx
University of York
CNR
Aristotle University of Thessaloniki
ENEA Centro Ricerche Frascati
University of Seville
National and Kapodistrian University of Athens
Università degli Studi di Catania
Max-Planck-Institut für Plasmaphysik
University of California, San Diego
FOM Institute DIFFER
Eindhoven University of Technology
Culham Centre for Fusion Energy
University of Rome Tor Vergata
Politecnico di Milano
Institute of Plasma Physics, Academy of Sciences of the Czech Republic
Université Aix Marseille
KU Leuven
University of Milano-Bicocca
Institute of Plasma Physics and Laser Microfusion
Commissariat à l'Énergie Atomique (CEA)
Jozef Stefan Institute
National Institute for Laser, Plasma and Radiation Physics
University of Ghent
University of Napoli 'Federico II'
Second University of Napoli
Inst. of Plasma Physics of the National Science Center, Kharkiv Institute of Physics and Technology
Instituto Superior Técnico
Chalmers University of Technology
KTH Royal Institute of Technology
Technical University of Denmark
MIT Plasma Science and Fusion Center
Royal Military Academy
Austrian Academy of Science
Ecole Polytechnique
Universitat Innsbruck
Institute of Nuclear Physics PAN
Aalto University
VTT Technical Research Centre of Finland
University of Ljubljana
Narodowe Centrum Badań Jadrowych
University of Tuscia
Universidad Carlos III de Madrid
Tokamak Energy
Padova University
Centre for Energy Research
University of Liverpool
Laboratorio Nacional de Fusión
ITER
FORSCHUNGSZENTRUM JULICH GMBH

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

27 Citations (Scopus)

Résumé

Tokamak à configuration variable (TCV), recently celebrating 30 years of near-continual operation, continues in its missions to advance outstanding key physics and operational scenario issues for ITER and the design of future power plants such as DEMO. The main machine heating systems and operational changes are first described. Then follow five sections: plasma scenarios. ITER Base-Line (IBL) discharges, triangularity studies together with X3 heating and N2 seeding. Edge localised mode suppression, with a high radiation region near the X-point is reported with N₂ injection with and without divertor baffles in a snowflake configuration. Negative triangularity (NT) discharges attained record, albeit transient, β_N ∼ 3 with lower turbulence, higher low-Z impurity transport, vertical stability and density limits and core transport better than the IBL. Positive triangularity L-Mode linear and saturated ohmic confinement confinement saturation, often-correlated with intrinsic toroidal rotation reversals, was probed for D, H and He working gases. H-mode confinement and pedestal studies were extended to low collisionality with electron cyclotron heating obtaining steady state electron iternal transport barrier with neutral beam heating (NBH), and NBH driven H-mode configurations with off-axis co-electron cyclotron current drive. Fast particle physics. The physics of disruptions, runaway electrons and fast ions (FIs) was developed using near-full current conversion at disruption with recombination thresholds characterised for impurity species (Ne, Ar, Kr). Different flushing gases (D2, H2) and pathways to trigger a benign disruption were explored. The 55 kV NBH II generated a rich Alfvénic spectrum modulating the FI fas ion loss detector signal. NT configurations showed less toroidal Alfvén excitation activity preferentially affecting higher FI pitch angles. Scrape-off layer and edge physics. gas puff imaging systems characterised turbulent plasma ejection for several advanced divertor configurations, including NT. Combined diagnostic array divertor state analysis in detachment conditions was compared to modelling revealing an importance for molecular processes. Divertor physics. Internal gas baffles diversified to include shorter/longer structures on the high and/or low field side to probe compressive efficiency. Divertor studies concentrated upon mitigating target power, facilitating detachment and increasing the radiated power fraction employing alternative divertor geometries, optimised X-point radiator regimes and long-legged configurations. Smaller-than-expected improvements with total flux expansion were better modelled when including parallel flows. Peak outer target heat flux reduction was achieved (>50%) for high flux-expansion geometries, maintaining core performance (H₉₈ > 1). A reduction in target heat loads and facilitated detachment access at lower core densities is reported. Real-time control. TCV’s real-time control upgrades employed MIMO gas injector control of stable, robust, partial detachment and plasma β feedback control avoiding neoclassical tearing modes with plasma confinement changes. Machine-learning enhancements include trajectory tracking disruption proximity and avoidance as well as a first-of-its-kind reinforcement learning-based controller for the plasma equilibrium trained entirely on a free-boundary simulator. Finally, a short description of TCV’s immediate future plans will be given.

langue originale	Anglais
Numéro d'article	112023
journal	Nuclear Fusion
Volume	64
Numéro de publication	11
Les DOIs	https://doi.org/10.1088/1741-4326/ad8361
état	Publié - nov. 2024

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10.1088/1741-4326/ad8361

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Contient cette citation

Duval, B. P., Abdolmaleki, A., Agostini, M., Ajay, C. J., Alberti, S., Alessi, E., Anastasiou, G., Andrèbe, Y., Apruzzese, G. M., Auriemma, F., Ayllon-Guerola, J., Bagnato, F., Baillod, A., Bairaktaris, F., Balbinot, L., Balestri, A., Baquero-Ruiz, M., Barcellona, C., Bernert, M., ... Zurita, M. (2024). Experimental research on the TCV tokamak. Nuclear Fusion, 64(11), Article 112023. https://doi.org/10.1088/1741-4326/ad8361

@article{f58383c90bd6467893e6c6921fa8599b,

title = "Experimental research on the TCV tokamak",

abstract = "Tokamak {\`a} configuration variable (TCV), recently celebrating 30 years of near-continual operation, continues in its missions to advance outstanding key physics and operational scenario issues for ITER and the design of future power plants such as DEMO. The main machine heating systems and operational changes are first described. Then follow five sections: plasma scenarios. ITER Base-Line (IBL) discharges, triangularity studies together with X3 heating and N2 seeding. Edge localised mode suppression, with a high radiation region near the X-point is reported with N2 injection with and without divertor baffles in a snowflake configuration. Negative triangularity (NT) discharges attained record, albeit transient, βN ∼ 3 with lower turbulence, higher low-Z impurity transport, vertical stability and density limits and core transport better than the IBL. Positive triangularity L-Mode linear and saturated ohmic confinement confinement saturation, often-correlated with intrinsic toroidal rotation reversals, was probed for D, H and He working gases. H-mode confinement and pedestal studies were extended to low collisionality with electron cyclotron heating obtaining steady state electron iternal transport barrier with neutral beam heating (NBH), and NBH driven H-mode configurations with off-axis co-electron cyclotron current drive. Fast particle physics. The physics of disruptions, runaway electrons and fast ions (FIs) was developed using near-full current conversion at disruption with recombination thresholds characterised for impurity species (Ne, Ar, Kr). Different flushing gases (D2, H2) and pathways to trigger a benign disruption were explored. The 55 kV NBH II generated a rich Alfv{\'e}nic spectrum modulating the FI fas ion loss detector signal. NT configurations showed less toroidal Alfv{\'e}n excitation activity preferentially affecting higher FI pitch angles. Scrape-off layer and edge physics. gas puff imaging systems characterised turbulent plasma ejection for several advanced divertor configurations, including NT. Combined diagnostic array divertor state analysis in detachment conditions was compared to modelling revealing an importance for molecular processes. Divertor physics. Internal gas baffles diversified to include shorter/longer structures on the high and/or low field side to probe compressive efficiency. Divertor studies concentrated upon mitigating target power, facilitating detachment and increasing the radiated power fraction employing alternative divertor geometries, optimised X-point radiator regimes and long-legged configurations. Smaller-than-expected improvements with total flux expansion were better modelled when including parallel flows. Peak outer target heat flux reduction was achieved (>50\%) for high flux-expansion geometries, maintaining core performance (H98 > 1). A reduction in target heat loads and facilitated detachment access at lower core densities is reported. Real-time control. TCV{\textquoteright}s real-time control upgrades employed MIMO gas injector control of stable, robust, partial detachment and plasma β feedback control avoiding neoclassical tearing modes with plasma confinement changes. Machine-learning enhancements include trajectory tracking disruption proximity and avoidance as well as a first-of-its-kind reinforcement learning-based controller for the plasma equilibrium trained entirely on a free-boundary simulator. Finally, a short description of TCV{\textquoteright}s immediate future plans will be given.",

keywords = "EPFL, SPC, TCV, plasma, review",

author = "Duval, \{B. P.\} and A. Abdolmaleki and M. Agostini and Ajay, \{C. J.\} and S. Alberti and E. Alessi and G. Anastasiou and Y. Andr{\`e}be and Apruzzese, \{G. M.\} and F. Auriemma and J. Ayllon-Guerola and F. Bagnato and A. Baillod and F. Bairaktaris and L. Balbinot and A. Balestri and M. Baquero-Ruiz and C. Barcellona and M. Bernert and W. Bin and P. Blanchard and J. Boedo and T. Bolzonella and F. Bombarda and L. Boncagni and M. Bonotto and Bosman, \{T. O.S.J.\} and D. Brida and D. Brunetti and J. Buchli and J. Buerman and P. Buratti and A. Burckhart and D. Busil and J. Caloud and Y. Camenen and A. Cardinali and S. Carli and D. Carnevale and F. Carpanese and M. Carpita and C. Castaldo and F. Causa and J. Cavalier and M. Cavedon and Cazabonne, \{J. A.\} and J. Cerovsky and B. Chapman and M. Chernyshova and P. Chmielewski and A. Chomiczewska and G. Ciraolo and S. Coda and C. Colandrea and C. Contr{\'e} and R. Coosemans and L. Cordaro and S. Costea and T. Craciunescu and K. Crombe and \{Dal Molin\}, A. and O. D{\textquoteright}Arcangelo and \{de Las Casas\}, D. and J. Decker and J. Degrave and \{de Oliveira\}, H. and Derks, \{G. L.\} and \{di Grazia\}, \{L. E.\} and C. Donner and M. Dreval and Dunne, \{M. G.\} and G. Durr-Legoupil-Nicoud and B. Esposito and T. Ewalds and M. Faitsch and M. Farn{\'i}k and A. Fasoli and F. Felici and J. Ferreira and O. F{\'e}vrier and O. Ficker and A. Frank and E. Fransson and L. Frassinetti and L. Fritz and I. Furno and D. Galassi and K. Ga{\l}{\c a}zka and J. Galdon-Quiroga and S. Galeani and C. Galperti and S. Garavaglia and M. Garcia-Munoz and P. Gaudio and M. Gelfusa and J. Genoud and \{Gerr{\'u} Miguelanez\}, R. and G. Ghillardi and M. Giacomin and L. Gil and A. Gillgren and C. Giroud and T. Golfinopoulos and T. Goodman and G. Gorini and S. Gorno and G. Grenfell and M. Griener and M. Gruca and T. Gyergyek and R. Hafner and M. Hamed and D. Hamm and W. Han and G. Harrer and Harrison, \{J. R.\} and D. Hassabis and S. Henderson and P. Hennequin and J. Hidalgo-Salaverri and Hogge, \{J. P.\} and M. Hoppe and J. Horacek and A. Huber and E. Huett and A. Iantchenko and P. Innocente and C. Ionita-Schrittwieser and \{Ivanova Stanik\}, I. and M. Jablczynska and \{van Vuuren\}, \{A. Jansen\} and A. Jardin and H. J{\"a}rleblad and J{\"a}rvinen, \{A. E.\} and J. Kalis and R. Karimov and Karpushov, \{A. N.\} and K. Kavukcuoglu and J. Kay and Y. Kazakov and J. Keeling and A. Kirjasuo and Koenders, \{J. T.W.\} and P. Kohli and M. Komm and M. Kong and J. Kovacic and E. Kowalska-Strzeciwilk and O. Krutkin and O. Kudlacek and U. Kumar and R. Kwiatkowski and B. Labit and L. Laguardia and E. Laszynska and A. Lazaros and K. Lee and E. Lerche and B. Linehan and D. Liuzza and T. Lunt and E. Macusova and D. Mancini and P. Mantica and M. Maraschek and G. Marceca and S. Marchioni and A. Mariani and M. Marin and A. Marinoni and L. Martellucci and Y. Martin and P. Martin and L. Martinelli and F. Martinelli and Martin-Solis, \{J. R.\} and S. Masillo and R. Masocco and V. Masson and A. Mathews and M. Mattei and D. Mazon and S. Mazzi and S. Mazzi and Medvedev, \{S. Y.\} and C. Meineri and A. Mele and V. Menkovski and A. Merle and H. Meyer and K. Mikszuta-Michalik and Miron, \{I. G.\} and \{Molina Cabrera\}, \{P. A.\} and A. Moro and A. Murari and P. Muscente and D. Mykytchuk and F. Nabais and F. Napoli and Nem, \{R. D.\} and M. Neunert and Nielsen, \{S. K.\} and A. Nielsen and M. Nocente and S. Noury and S. Nowak and H. Nystr{\"o}m and N. Offeddu and S. Olasz and F. Oliva and Oliveira, \{D. S.\} and Orsitto, \{F. P.\} and N. Osborne and Dominguez, \{P. Oyola\} and O. Pan and E. Panontin and Papadopoulos, \{A. D.\} and P. Papagiannis and G. Papp and M. Passoni and F. Pastore and A. Pau and Pavlichenko, \{R. O.\} and Pedersen, \{A. C.\} and M. Pedrini and G. Pelka and E. Peluso and A. Perek and \{Von Thun\}, \{C. Perez\} and F. Pesamosca and D. Pfau and V. Piergotti and L. Pigatto and C. Piron and L. Piron and A. Pironti and U. Plank and V. Plyusnin and Poels, \{Y. R.J.\} and Pokol, \{G. I.\} and J. Poley-Sanjuan and M. Poradzinski and L. Porte and C. Possieri and A. Poulsen and Pueschel, \{M. J.\} and T. P{\"u}tterich and V. Quadri and M. Rabinski and R. Ragona and H. Raj and A. Redl and H. Reimerdes and C. Reux and D. Ricci and M. Riedmiller and S. Rien{\"a}cker and D. Rigamonti and N. Rispoli and Rivero-Rodriguez, \{J. F.\} and Madrid, \{C. F.Romero\} and Rueda, \{J. Rueda\} and Ryan, \{P. J.\} and M. Salewski and A. Salmi and M. Sassano and O. Sauter and N. Schoonheere and Schrittwieser, \{R. W.\} and F. Sciortino and A. Selce and L. Senni and S. Sharapov and Sheikh, \{U. A.\} and B. Sieglin and M. Silva and D. Silvagni and Schmidt, \{B. Simmendefeldt\} and L. Simons and Solano, \{E. R.\} and C. Sozzi and M. Spolaore and L. Spolladore and A. Stagni and P. Strand and G. Sun and W. Suttrop and J. Svoboda and B. Tal and T. Tala and P. Tamain and M. Tardocchi and Biwole, \{A. Tema\} and A. Tenaglia and D. Terranova and D. Testa and C. Theiler and A. Thornton and Thrysoe, \{A. S.\} and M. Tomes and E. Tonello and H. Torreblanca and B. Tracey and M. Tsimpoukelli and C. Tsironis and Tsui, \{C. K.\} and M. Ugoletti and M. Vallar and \{van Berkel\}, M. and \{van Mulders\}, S. and \{van Rossem\}, M. and C. Venturini and M. Veranda and T. Verdier and K. Verhaegh and L. Vermare and N. Vianello and E. Viezzer and F. Villone and B. Vincent and P. Vincenzi and I. Voitsekhovitch and L. Votta and Vu, \{N. M.T.\} and Y. Wang and E. Wang and T. Wauters and M. Weiland and H. Weisen and N. Wendler and S. Wiesen and M. Wiesenberger and T. Wijkamp and C. W{\"u}thrich and D. Yadykin and H. Yang and V. Yanovskiy and J. Zebrowski and P. Zestanakis and M. Zuin and M. Zurita",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s).",

year = "2024",

month = nov,

doi = "10.1088/1741-4326/ad8361",

language = "English",

volume = "64",

journal = "Nuclear Fusion",

issn = "0029-5515",

number = "11",

}

Duval, BP, Abdolmaleki, A, Agostini, M, Ajay, CJ, Alberti, S, Alessi, E, Anastasiou, G, Andrèbe, Y, Apruzzese, GM, Auriemma, F, Ayllon-Guerola, J, Bagnato, F, Baillod, A, Bairaktaris, F, Balbinot, L, Balestri, A, Baquero-Ruiz, M, Barcellona, C, Bernert, M, Bin, W, Blanchard, P, Boedo, J, Bolzonella, T, Bombarda, F, Boncagni, L, Bonotto, M, Bosman, TOSJ, Brida, D, Brunetti, D, Buchli, J, Buerman, J, Buratti, P, Burckhart, A, Busil, D, Caloud, J, Camenen, Y, Cardinali, A, Carli, S, Carnevale, D, Carpanese, F, Carpita, M, Castaldo, C, Causa, F, Cavalier, J, Cavedon, M, Cazabonne, JA, Cerovsky, J, Chapman, B, Chernyshova, M, Chmielewski, P, Chomiczewska, A, Ciraolo, G, Coda, S, Colandrea, C, Contré, C, Coosemans, R, Cordaro, L, Costea, S, Craciunescu, T, Crombe, K, Dal Molin, A, D’Arcangelo, O, de Las Casas, D, Decker, J, Degrave, J, de Oliveira, H, Derks, GL, di Grazia, LE, Donner, C, Dreval, M, Dunne, MG, Durr-Legoupil-Nicoud, G, Esposito, B, Ewalds, T, Faitsch, M, Farník, M, Fasoli, A, Felici, F, Ferreira, J, Février, O, Ficker, O, Frank, A, Fransson, E, Frassinetti, L, Fritz, L, Furno, I, Galassi, D, Gałązka, K, Galdon-Quiroga, J, Galeani, S, Galperti, C, Garavaglia, S, Garcia-Munoz, M, Gaudio, P, Gelfusa, M, Genoud, J, Gerrú Miguelanez, R, Ghillardi, G, Giacomin, M, Gil, L, Gillgren, A, Giroud, C, Golfinopoulos, T, Goodman, T, Gorini, G, Gorno, S, Grenfell, G, Griener, M, Gruca, M, Gyergyek, T, Hafner, R, Hamed, M, Hamm, D, Han, W, Harrer, G, Harrison, JR, Hassabis, D, Henderson, S, Hennequin, P, Hidalgo-Salaverri, J, Hogge, JP, Hoppe, M, Horacek, J, Huber, A, Huett, E, Iantchenko, A, Innocente, P, Ionita-Schrittwieser, C, Ivanova Stanik, I, Jablczynska, M, van Vuuren, AJ, Jardin, A, Järleblad, H, Järvinen, AE, Kalis, J, Karimov, R, Karpushov, AN, Kavukcuoglu, K, Kay, J, Kazakov, Y, Keeling, J, Kirjasuo, A, Koenders, JTW, Kohli, P, Komm, M, Kong, M, Kovacic, J, Kowalska-Strzeciwilk, E, Krutkin, O, Kudlacek, O, Kumar, U, Kwiatkowski, R, Labit, B, Laguardia, L, Laszynska, E, Lazaros, A, Lee, K, Lerche, E, Linehan, B, Liuzza, D, Lunt, T, Macusova, E, Mancini, D, Mantica, P, Maraschek, M, Marceca, G, Marchioni, S, Mariani, A, Marin, M, Marinoni, A, Martellucci, L, Martin, Y, Martin, P, Martinelli, L, Martinelli, F, Martin-Solis, JR, Masillo, S, Masocco, R, Masson, V, Mathews, A, Mattei, M, Mazon, D, Mazzi, S, Mazzi, S, Medvedev, SY, Meineri, C, Mele, A, Menkovski, V, Merle, A, Meyer, H, Mikszuta-Michalik, K, Miron, IG, Molina Cabrera, PA, Moro, A, Murari, A, Muscente, P, Mykytchuk, D, Nabais, F, Napoli, F, Nem, RD, Neunert, M, Nielsen, SK, Nielsen, A, Nocente, M, Noury, S, Nowak, S, Nyström, H, Offeddu, N, Olasz, S, Oliva, F, Oliveira, DS, Orsitto, FP, Osborne, N, Dominguez, PO, Pan, O, Panontin, E, Papadopoulos, AD, Papagiannis, P, Papp, G, Passoni, M, Pastore, F, Pau, A, Pavlichenko, RO, Pedersen, AC, Pedrini, M, Pelka, G, Peluso, E, Perek, A, Von Thun, CP, Pesamosca, F, Pfau, D, Piergotti, V, Pigatto, L, Piron, C, Piron, L, Pironti, A, Plank, U, Plyusnin, V, Poels, YRJ, Pokol, GI, Poley-Sanjuan, J, Poradzinski, M, Porte, L, Possieri, C, Poulsen, A, Pueschel, MJ, Pütterich, T, Quadri, V, Rabinski, M, Ragona, R, Raj, H, Redl, A, Reimerdes, H, Reux, C, Ricci, D, Riedmiller, M, Rienäcker, S, Rigamonti, D, Rispoli, N, Rivero-Rodriguez, JF, Madrid, CFR, Rueda, JR, Ryan, PJ, Salewski, M, Salmi, A, Sassano, M, Sauter, O, Schoonheere, N, Schrittwieser, RW, Sciortino, F, Selce, A, Senni, L, Sharapov, S, Sheikh, UA, Sieglin, B, Silva, M, Silvagni, D, Schmidt, BS, Simons, L, Solano, ER, Sozzi, C, Spolaore, M, Spolladore, L, Stagni, A, Strand, P, Sun, G, Suttrop, W, Svoboda, J, Tal, B, Tala, T, Tamain, P, Tardocchi, M, Biwole, AT, Tenaglia, A, Terranova, D, Testa, D, Theiler, C, Thornton, A, Thrysoe, AS, Tomes, M, Tonello, E, Torreblanca, H, Tracey, B, Tsimpoukelli, M, Tsironis, C, Tsui, CK, Ugoletti, M, Vallar, M, van Berkel, M, van Mulders, S, van Rossem, M, Venturini, C, Veranda, M, Verdier, T, Verhaegh, K, Vermare, L, Vianello, N, Viezzer, E, Villone, F, Vincent, B, Vincenzi, P, Voitsekhovitch, I, Votta, L, Vu, NMT, Wang, Y, Wang, E, Wauters, T, Weiland, M, Weisen, H, Wendler, N, Wiesen, S, Wiesenberger, M, Wijkamp, T, Wüthrich, C, Yadykin, D, Yang, H, Yanovskiy, V, Zebrowski, J, Zestanakis, P, Zuin, M & Zurita, M 2024, 'Experimental research on the TCV tokamak', Nuclear Fusion, VOL. 64, Numéro 11, 112023. https://doi.org/10.1088/1741-4326/ad8361

TY - JOUR

T1 - Experimental research on the TCV tokamak

AU - Duval, B. P.

AU - Abdolmaleki, A.

AU - Agostini, M.

AU - Ajay, C. J.

AU - Alberti, S.

AU - Alessi, E.

AU - Anastasiou, G.

AU - Andrèbe, Y.

AU - Apruzzese, G. M.

AU - Auriemma, F.

AU - Ayllon-Guerola, J.

AU - Bagnato, F.

AU - Baillod, A.

AU - Bairaktaris, F.

AU - Balbinot, L.

AU - Balestri, A.

AU - Baquero-Ruiz, M.

AU - Barcellona, C.

AU - Bernert, M.

AU - Bin, W.

AU - Blanchard, P.

AU - Boedo, J.

AU - Bolzonella, T.

AU - Bombarda, F.

AU - Boncagni, L.

AU - Bonotto, M.

AU - Bosman, T. O.S.J.

AU - Brida, D.

AU - Brunetti, D.

AU - Buchli, J.

AU - Buerman, J.

AU - Buratti, P.

AU - Burckhart, A.

AU - Busil, D.

AU - Caloud, J.

AU - Camenen, Y.

AU - Cardinali, A.

AU - Carli, S.

AU - Carnevale, D.

AU - Carpanese, F.

AU - Carpita, M.

AU - Castaldo, C.

AU - Causa, F.

AU - Cavalier, J.

AU - Cavedon, M.

AU - Cazabonne, J. A.

AU - Cerovsky, J.

AU - Chapman, B.

AU - Chernyshova, M.

AU - Chmielewski, P.

AU - Chomiczewska, A.

AU - Ciraolo, G.

AU - Coda, S.

AU - Colandrea, C.

AU - Contré, C.

AU - Coosemans, R.

AU - Cordaro, L.

AU - Costea, S.

AU - Craciunescu, T.

AU - Crombe, K.

AU - Dal Molin, A.

AU - D’Arcangelo, O.

AU - de Las Casas, D.

AU - Decker, J.

AU - Degrave, J.

AU - de Oliveira, H.

AU - Derks, G. L.

AU - di Grazia, L. E.

AU - Donner, C.

AU - Dreval, M.

AU - Dunne, M. G.

AU - Durr-Legoupil-Nicoud, G.

AU - Esposito, B.

AU - Ewalds, T.

AU - Faitsch, M.

AU - Farník, M.

AU - Fasoli, A.

AU - Felici, F.

AU - Ferreira, J.

AU - Février, O.

AU - Ficker, O.

AU - Frank, A.

AU - Fransson, E.

AU - Frassinetti, L.

AU - Fritz, L.

AU - Furno, I.

AU - Galassi, D.

AU - Gałązka, K.

AU - Galdon-Quiroga, J.

AU - Galeani, S.

AU - Galperti, C.

AU - Garavaglia, S.

AU - Garcia-Munoz, M.

AU - Gaudio, P.

AU - Gelfusa, M.

AU - Genoud, J.

AU - Gerrú Miguelanez, R.

AU - Ghillardi, G.

AU - Giacomin, M.

AU - Gil, L.

AU - Gillgren, A.

AU - Giroud, C.

AU - Golfinopoulos, T.

AU - Goodman, T.

AU - Gorini, G.

AU - Gorno, S.

AU - Grenfell, G.

AU - Griener, M.

AU - Gruca, M.

AU - Gyergyek, T.

AU - Hafner, R.

AU - Hamed, M.

AU - Hamm, D.

AU - Han, W.

AU - Harrer, G.

AU - Harrison, J. R.

AU - Hassabis, D.

AU - Henderson, S.

AU - Hennequin, P.

AU - Hidalgo-Salaverri, J.

AU - Hogge, J. P.

AU - Hoppe, M.

AU - Horacek, J.

AU - Huber, A.

AU - Huett, E.

AU - Iantchenko, A.

AU - Innocente, P.

AU - Ionita-Schrittwieser, C.

AU - Ivanova Stanik, I.

AU - Jablczynska, M.

AU - van Vuuren, A. Jansen

AU - Jardin, A.

AU - Järleblad, H.

AU - Järvinen, A. E.

AU - Kalis, J.

AU - Karimov, R.

AU - Karpushov, A. N.

AU - Kavukcuoglu, K.

AU - Kay, J.

AU - Kazakov, Y.

AU - Keeling, J.

AU - Kirjasuo, A.

AU - Koenders, J. T.W.

AU - Kohli, P.

AU - Komm, M.

AU - Kong, M.

AU - Kovacic, J.

AU - Kowalska-Strzeciwilk, E.

AU - Krutkin, O.

AU - Kudlacek, O.

AU - Kumar, U.

AU - Kwiatkowski, R.

AU - Labit, B.

AU - Laguardia, L.

AU - Laszynska, E.

AU - Lazaros, A.

AU - Lee, K.

AU - Lerche, E.

AU - Linehan, B.

AU - Liuzza, D.

AU - Lunt, T.

AU - Macusova, E.

AU - Mancini, D.

AU - Mantica, P.

AU - Maraschek, M.

AU - Marceca, G.

AU - Marchioni, S.

AU - Mariani, A.

AU - Marin, M.

AU - Marinoni, A.

AU - Martellucci, L.

AU - Martin, Y.

AU - Martin, P.

AU - Martinelli, L.

AU - Martinelli, F.

AU - Martin-Solis, J. R.

AU - Masillo, S.

AU - Masocco, R.

AU - Masson, V.

AU - Mathews, A.

AU - Mattei, M.

AU - Mazon, D.

AU - Mazzi, S.

AU - Medvedev, S. Y.

AU - Meineri, C.

AU - Mele, A.

AU - Menkovski, V.

AU - Merle, A.

AU - Meyer, H.

AU - Mikszuta-Michalik, K.

AU - Miron, I. G.

AU - Molina Cabrera, P. A.

AU - Moro, A.

AU - Murari, A.

AU - Muscente, P.

AU - Mykytchuk, D.

AU - Nabais, F.

AU - Napoli, F.

AU - Nem, R. D.

AU - Neunert, M.

AU - Nielsen, S. K.

AU - Nielsen, A.

AU - Nocente, M.

AU - Noury, S.

AU - Nowak, S.

AU - Nyström, H.

AU - Offeddu, N.

AU - Olasz, S.

AU - Oliva, F.

AU - Oliveira, D. S.

AU - Orsitto, F. P.

AU - Osborne, N.

AU - Dominguez, P. Oyola

AU - Pan, O.

AU - Panontin, E.

AU - Papadopoulos, A. D.

AU - Papagiannis, P.

AU - Papp, G.

AU - Passoni, M.

AU - Pastore, F.

AU - Pau, A.

AU - Pavlichenko, R. O.

AU - Pedersen, A. C.

AU - Pedrini, M.

AU - Pelka, G.

AU - Peluso, E.

AU - Perek, A.

AU - Von Thun, C. Perez

AU - Pesamosca, F.

AU - Pfau, D.

AU - Piergotti, V.

AU - Pigatto, L.

AU - Piron, C.

AU - Piron, L.

AU - Pironti, A.

AU - Plank, U.

AU - Plyusnin, V.

AU - Poels, Y. R.J.

AU - Pokol, G. I.

AU - Poley-Sanjuan, J.

AU - Poradzinski, M.

AU - Porte, L.

AU - Possieri, C.

AU - Poulsen, A.

AU - Pueschel, M. J.

AU - Pütterich, T.

AU - Quadri, V.

AU - Rabinski, M.

AU - Ragona, R.

AU - Raj, H.

AU - Redl, A.

AU - Reimerdes, H.

AU - Reux, C.

AU - Ricci, D.

AU - Riedmiller, M.

AU - Rienäcker, S.

AU - Rigamonti, D.

AU - Rispoli, N.

AU - Rivero-Rodriguez, J. F.

AU - Madrid, C. F.Romero

AU - Rueda, J. Rueda

AU - Ryan, P. J.

AU - Salewski, M.

AU - Salmi, A.

AU - Sassano, M.

AU - Sauter, O.

AU - Schoonheere, N.

AU - Schrittwieser, R. W.

AU - Sciortino, F.

AU - Selce, A.

AU - Senni, L.

AU - Sharapov, S.

AU - Sheikh, U. A.

AU - Sieglin, B.

AU - Silva, M.

AU - Silvagni, D.

AU - Schmidt, B. Simmendefeldt

AU - Simons, L.

AU - Solano, E. R.

AU - Sozzi, C.

AU - Spolaore, M.

AU - Spolladore, L.

AU - Stagni, A.

AU - Strand, P.

AU - Sun, G.

AU - Suttrop, W.

AU - Svoboda, J.

AU - Tal, B.

AU - Tala, T.

AU - Tamain, P.

AU - Tardocchi, M.

AU - Biwole, A. Tema

AU - Tenaglia, A.

AU - Terranova, D.

AU - Testa, D.

AU - Theiler, C.

AU - Thornton, A.

AU - Thrysoe, A. S.

AU - Tomes, M.

AU - Tonello, E.

AU - Torreblanca, H.

AU - Tracey, B.

AU - Tsimpoukelli, M.

AU - Tsironis, C.

AU - Tsui, C. K.

AU - Ugoletti, M.

AU - Vallar, M.

AU - van Berkel, M.

AU - van Mulders, S.

AU - van Rossem, M.

AU - Venturini, C.

AU - Veranda, M.

AU - Verdier, T.

AU - Verhaegh, K.

AU - Vermare, L.

AU - Vianello, N.

AU - Viezzer, E.

AU - Villone, F.

AU - Vincent, B.

AU - Vincenzi, P.

AU - Voitsekhovitch, I.

AU - Votta, L.

AU - Vu, N. M.T.

AU - Wang, Y.

AU - Wang, E.

AU - Wauters, T.

AU - Weiland, M.

AU - Weisen, H.

AU - Wendler, N.

AU - Wiesen, S.

AU - Wiesenberger, M.

AU - Wijkamp, T.

AU - Wüthrich, C.

AU - Yadykin, D.

AU - Yang, H.

AU - Yanovskiy, V.

AU - Zebrowski, J.

AU - Zestanakis, P.

AU - Zuin, M.

AU - Zurita, M.

PY - 2024/11

Y1 - 2024/11

N2 - Tokamak à configuration variable (TCV), recently celebrating 30 years of near-continual operation, continues in its missions to advance outstanding key physics and operational scenario issues for ITER and the design of future power plants such as DEMO. The main machine heating systems and operational changes are first described. Then follow five sections: plasma scenarios. ITER Base-Line (IBL) discharges, triangularity studies together with X3 heating and N2 seeding. Edge localised mode suppression, with a high radiation region near the X-point is reported with N2 injection with and without divertor baffles in a snowflake configuration. Negative triangularity (NT) discharges attained record, albeit transient, βN ∼ 3 with lower turbulence, higher low-Z impurity transport, vertical stability and density limits and core transport better than the IBL. Positive triangularity L-Mode linear and saturated ohmic confinement confinement saturation, often-correlated with intrinsic toroidal rotation reversals, was probed for D, H and He working gases. H-mode confinement and pedestal studies were extended to low collisionality with electron cyclotron heating obtaining steady state electron iternal transport barrier with neutral beam heating (NBH), and NBH driven H-mode configurations with off-axis co-electron cyclotron current drive. Fast particle physics. The physics of disruptions, runaway electrons and fast ions (FIs) was developed using near-full current conversion at disruption with recombination thresholds characterised for impurity species (Ne, Ar, Kr). Different flushing gases (D2, H2) and pathways to trigger a benign disruption were explored. The 55 kV NBH II generated a rich Alfvénic spectrum modulating the FI fas ion loss detector signal. NT configurations showed less toroidal Alfvén excitation activity preferentially affecting higher FI pitch angles. Scrape-off layer and edge physics. gas puff imaging systems characterised turbulent plasma ejection for several advanced divertor configurations, including NT. Combined diagnostic array divertor state analysis in detachment conditions was compared to modelling revealing an importance for molecular processes. Divertor physics. Internal gas baffles diversified to include shorter/longer structures on the high and/or low field side to probe compressive efficiency. Divertor studies concentrated upon mitigating target power, facilitating detachment and increasing the radiated power fraction employing alternative divertor geometries, optimised X-point radiator regimes and long-legged configurations. Smaller-than-expected improvements with total flux expansion were better modelled when including parallel flows. Peak outer target heat flux reduction was achieved (>50%) for high flux-expansion geometries, maintaining core performance (H98 > 1). A reduction in target heat loads and facilitated detachment access at lower core densities is reported. Real-time control. TCV’s real-time control upgrades employed MIMO gas injector control of stable, robust, partial detachment and plasma β feedback control avoiding neoclassical tearing modes with plasma confinement changes. Machine-learning enhancements include trajectory tracking disruption proximity and avoidance as well as a first-of-its-kind reinforcement learning-based controller for the plasma equilibrium trained entirely on a free-boundary simulator. Finally, a short description of TCV’s immediate future plans will be given.

AB - Tokamak à configuration variable (TCV), recently celebrating 30 years of near-continual operation, continues in its missions to advance outstanding key physics and operational scenario issues for ITER and the design of future power plants such as DEMO. The main machine heating systems and operational changes are first described. Then follow five sections: plasma scenarios. ITER Base-Line (IBL) discharges, triangularity studies together with X3 heating and N2 seeding. Edge localised mode suppression, with a high radiation region near the X-point is reported with N2 injection with and without divertor baffles in a snowflake configuration. Negative triangularity (NT) discharges attained record, albeit transient, βN ∼ 3 with lower turbulence, higher low-Z impurity transport, vertical stability and density limits and core transport better than the IBL. Positive triangularity L-Mode linear and saturated ohmic confinement confinement saturation, often-correlated with intrinsic toroidal rotation reversals, was probed for D, H and He working gases. H-mode confinement and pedestal studies were extended to low collisionality with electron cyclotron heating obtaining steady state electron iternal transport barrier with neutral beam heating (NBH), and NBH driven H-mode configurations with off-axis co-electron cyclotron current drive. Fast particle physics. The physics of disruptions, runaway electrons and fast ions (FIs) was developed using near-full current conversion at disruption with recombination thresholds characterised for impurity species (Ne, Ar, Kr). Different flushing gases (D2, H2) and pathways to trigger a benign disruption were explored. The 55 kV NBH II generated a rich Alfvénic spectrum modulating the FI fas ion loss detector signal. NT configurations showed less toroidal Alfvén excitation activity preferentially affecting higher FI pitch angles. Scrape-off layer and edge physics. gas puff imaging systems characterised turbulent plasma ejection for several advanced divertor configurations, including NT. Combined diagnostic array divertor state analysis in detachment conditions was compared to modelling revealing an importance for molecular processes. Divertor physics. Internal gas baffles diversified to include shorter/longer structures on the high and/or low field side to probe compressive efficiency. Divertor studies concentrated upon mitigating target power, facilitating detachment and increasing the radiated power fraction employing alternative divertor geometries, optimised X-point radiator regimes and long-legged configurations. Smaller-than-expected improvements with total flux expansion were better modelled when including parallel flows. Peak outer target heat flux reduction was achieved (>50%) for high flux-expansion geometries, maintaining core performance (H98 > 1). A reduction in target heat loads and facilitated detachment access at lower core densities is reported. Real-time control. TCV’s real-time control upgrades employed MIMO gas injector control of stable, robust, partial detachment and plasma β feedback control avoiding neoclassical tearing modes with plasma confinement changes. Machine-learning enhancements include trajectory tracking disruption proximity and avoidance as well as a first-of-its-kind reinforcement learning-based controller for the plasma equilibrium trained entirely on a free-boundary simulator. Finally, a short description of TCV’s immediate future plans will be given.

KW - EPFL

KW - SPC

KW - TCV

KW - plasma

KW - review

UR - https://www.scopus.com/pages/publications/85208284964

U2 - 10.1088/1741-4326/ad8361

DO - 10.1088/1741-4326/ad8361

M3 - Article

AN - SCOPUS:85208284964

SN - 0029-5515

VL - 64

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 11

M1 - 112023

ER -

Experimental research on the TCV tokamak

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