Steady state advanced scenarios at ASDEX Upgrade

A. C.C. Sips; R. Arslanbekov; C. Atanasiu; W. Becker; G. Becker; K. Behler; K. Behringer; A. Bergmann; R. Bilato; D. Bolshukhin; K. Borrass; B. Braams; M. Brambilla; F. Braun; A. Buhler; G. Conway; D. Coster; R. Drube; R. Dux; S. Egorov; T. Eich; K. Engelhardt; H. U. Fahrbach; U. Fantz; H. Faugel; M. Foley; K. B. Fournier; P. Franzen; J. C. Fuchs; J. Gafert; G. Gantenbein; O. Gehre; A. Geier; J. Gernhardt; O. Gruber; A. Gude; S. Günter; G. Haas; D. Hartmann; B. Heger; B. Heinemann; A. Herrmann; J. Hobirk; F. Hofmeister; H. Hohenöcker; L. Horton; V. Igochine; D. Jacobi; M. Jakobi; F. Jenko; A. Kallenbach; O. Kardaun; M. Kaufmann; A. Keller; A. Kendl; J. W. Kim; K. Kirov; R. Kochergov; H. Kollotzek; W. Kraus; K. Krieger; B. Kurzan; P. T. Lang; P. Lauber; M. Laux; F. Leuterer; A. Lohs; A. Lorenz; C. Maggi; H. Maier; K. Mank; M. E. Manso; M. Maraschek; K. F. Mast; P. McCarthy; D. Meisel; H. Meister; F. Meo; R. Merkel; D. Merkl; V. Mertens; F. Monaco; A. Mück; H. W. Müller; M. Münich; H. Murmann; Y. S. Na; G. Neu; R. Neu; J. Neuhauser; J. M. Noterdaeme; I. Nunes; G. Pautasso; A. G. Peeters; G. Pereverzev; S. Pinches; E. Poli; M. Proschek; R. Pugno; E. Quigley; G. Raupp; T. Ribeiro; R. Riedl; S. Riondato; V. Rohde; J. Roth; F. Ryter; S. Saarelma; W. Sandmann; S. Schade; H. B. Schilling; W. Schneider; G. Schramm; S. Schweizer; B. Scott; U. Seidel; F. Serra; S. Sesnic; C. Sihler; A. Silva; E. Speth; A. Stäbler; K. H. Steuer; J. Stober; B. Streibl; E. Strumberger; W. Suttrop; A. Tabasso; A. Tanga; G. Tardini; C. Tichmann; W. Treutterer; M. Troppmann; P. Varela; O. Vollmer; D. Wagner; U. Wenzel; F. Wesner; R. Wolf; E. Wolfrum; E. Würsching; Q. Yu; D. Zasche; T. Zehetbauer; H. P. Zehrfeld; H. Zohm

doi:10.1088/0741-3335/44/12b/306

Steady state advanced scenarios at ASDEX Upgrade

A. C.C. Sips
, R. Arslanbekov
, C. Atanasiu
, W. Becker
, G. Becker
, K. Behler
, K. Behringer
, A. Bergmann
, R. Bilato
, D. Bolshukhin
, K. Borrass
, B. Braams
, M. Brambilla
, F. Braun
, A. Buhler
, G. Conway
, D. Coster
, R. Drube
, R. Dux
, S. Egorov

T. Eich, K. Engelhardt, H. U. Fahrbach, U. Fantz, H. Faugel, M. Foley, K. B. Fournier, P. Franzen, J. C. Fuchs, J. Gafert, G. Gantenbein, O. Gehre, A. Geier, J. Gernhardt, O. Gruber, A. Gude, S. Günter, G. Haas, D. Hartmann, B. Heger, B. Heinemann, A. Herrmann, J. Hobirk, F. Hofmeister, H. Hohenöcker, L. Horton, V. Igochine, D. Jacobi, M. Jakobi, F. Jenko, A. Kallenbach, O. Kardaun, M. Kaufmann, A. Keller, A. Kendl, J. W. Kim, K. Kirov, R. Kochergov, H. Kollotzek, W. Kraus, K. Krieger, B. Kurzan, P. T. Lang, P. Lauber, M. Laux, F. Leuterer, A. Lohs, A. Lorenz, C. Maggi, H. Maier, K. Mank, M. E. Manso, M. Maraschek, K. F. Mast, P. McCarthy, D. Meisel, H. Meister, F. Meo, R. Merkel, D. Merkl, V. Mertens, F. Monaco, A. Mück, H. W. Müller, M. Münich, H. Murmann, Y. S. Na, G. Neu, R. Neu, J. Neuhauser, J. M. Noterdaeme, I. Nunes, G. Pautasso, A. G. Peeters, G. Pereverzev, S. Pinches, E. Poli, M. Proschek, R. Pugno, E. Quigley, G. Raupp, T. Ribeiro, R. Riedl, S. Riondato, V. Rohde, J. Roth, F. Ryter, S. Saarelma, W. Sandmann, S. Schade, H. B. Schilling, W. Schneider, G. Schramm, S. Schweizer, B. Scott, U. Seidel, F. Serra, S. Sesnic, C. Sihler, A. Silva, E. Speth, A. Stäbler, K. H. Steuer, J. Stober, B. Streibl, E. Strumberger, W. Suttrop, A. Tabasso, A. Tanga, G. Tardini, C. Tichmann, W. Treutterer, M. Troppmann, P. Varela, O. Vollmer, D. Wagner, U. Wenzel, F. Wesner, R. Wolf, E. Wolfrum, E. Würsching, Q. Yu, D. Zasche, T. Zehetbauer, H. P. Zehrfeld, H. Zohm

Max Planck Institute for Plasma Physics
Institute of Atomic Physics
Princeton University
St. Petersburg Technical University
University Hospital Augsburg
University College Cork
Lawrence Livermore National Laboratory
Universität Stuttgart
Instituto Superior Técnico
IAP
VTT Technical Research Centre of Finland

Research output: Contribution to journal › Conference article › peer-review

121 Scopus citations

Abstract

Recent experiments at ASDEX Upgrade have achieved advanced scenarios with high fin (>3) and confinement enhancement over ITER98(y, 2) scaling, H^H98y2 = 1.1-1.5, in steady state. These discharges have been obtained in a modified divertor configuration for ASDEX Upgrade, allowing operation at higher triangularity, and with a changed neutral beam injection (NBI) system, for a more tangential, off-axis beam deposition. The figure of merit, β_NH^ITER89-P, reaches up to 7.5 for several seconds in plasmas approaching stationary conditions. These advanced tokamak discharges have low magnetic shear in the centre, with q on-axis near 1, and edge safety factor, q95 in the range 3.3-4.5. This q-profile is sustained by the bootstrap current, NBI-driven current and fishbone activity in the core. The off-axis heating leads to a strong peaking of the density profile and impurity accumulation in the core. This can be avoided by adding some central heating from ion cyclotron resonance heating or electron cyclotron resonance heating, since the temperature profiles are stiff in this advanced scenario (no internal transport barrier). Using a combination of NBI and gas fuelling line, average densities up to 80-90% of the Greenwald density are achieved, maintaining good confinement. The best integrated results in terms of confinement, stability and ability to operate at high density are obtained in highly shaped configurations, near double null, with δ = 0.43. At the highest densities, a strong reduction of the edge localized mode activity similar to type II activity is observed, providing a steady power load on the divertor, in the range of 6 MW m^-2, despite the high input power used (> 10 MW).

Original language	English
Pages (from-to)	B69-B83
Journal	Plasma Physics and Controlled Fusion
Volume	44
Issue number	12 B SPEC
DOIs	https://doi.org/10.1088/0741-3335/44/12b/306
State	Published - Dec 2002
Externally published	Yes
Event	29th European Physical Society Conference on Plasma Physics and Controlled Fusion - Montreux, Switzerland Duration: 17 Jun 2002 → 21 Jun 2002

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10.1088/0741-3335/44/12b/306

Cite this

Sips, A. C. C., Arslanbekov, R., Atanasiu, C., Becker, W., Becker, G., Behler, K., Behringer, K., Bergmann, A., Bilato, R., Bolshukhin, D., Borrass, K., Braams, B., Brambilla, M., Braun, F., Buhler, A., Conway, G., Coster, D., Drube, R., Dux, R., ... Zohm, H. (2002). Steady state advanced scenarios at ASDEX Upgrade. Plasma Physics and Controlled Fusion, 44(12 B SPEC), B69-B83. https://doi.org/10.1088/0741-3335/44/12b/306

@article{aecf85e0111a4b5fb95dc3863b8e34c2,

title = "Steady state advanced scenarios at ASDEX Upgrade",

abstract = "Recent experiments at ASDEX Upgrade have achieved advanced scenarios with high fin (>3) and confinement enhancement over ITER98(y, 2) scaling, HH98y2 = 1.1-1.5, in steady state. These discharges have been obtained in a modified divertor configuration for ASDEX Upgrade, allowing operation at higher triangularity, and with a changed neutral beam injection (NBI) system, for a more tangential, off-axis beam deposition. The figure of merit, βNHITER89-P, reaches up to 7.5 for several seconds in plasmas approaching stationary conditions. These advanced tokamak discharges have low magnetic shear in the centre, with q on-axis near 1, and edge safety factor, q95 in the range 3.3-4.5. This q-profile is sustained by the bootstrap current, NBI-driven current and fishbone activity in the core. The off-axis heating leads to a strong peaking of the density profile and impurity accumulation in the core. This can be avoided by adding some central heating from ion cyclotron resonance heating or electron cyclotron resonance heating, since the temperature profiles are stiff in this advanced scenario (no internal transport barrier). Using a combination of NBI and gas fuelling line, average densities up to 80-90\% of the Greenwald density are achieved, maintaining good confinement. The best integrated results in terms of confinement, stability and ability to operate at high density are obtained in highly shaped configurations, near double null, with δ = 0.43. At the highest densities, a strong reduction of the edge localized mode activity similar to type II activity is observed, providing a steady power load on the divertor, in the range of 6 MW m-2, despite the high input power used (> 10 MW).",

author = "Sips, \{A. C.C.\} and R. Arslanbekov and C. Atanasiu and W. Becker and G. Becker and K. Behler and K. Behringer and A. Bergmann and R. Bilato and D. Bolshukhin and K. Borrass and B. Braams and M. Brambilla and F. Braun and A. Buhler and G. Conway and D. Coster and R. Drube and R. Dux and S. Egorov and T. Eich and K. Engelhardt and Fahrbach, \{H. U.\} and U. Fantz and H. Faugel and M. Foley and Fournier, \{K. B.\} and P. Franzen and Fuchs, \{J. C.\} and J. Gafert and G. Gantenbein and O. Gehre and A. Geier and J. Gernhardt and O. Gruber and A. Gude and S. G{\"u}nter and G. Haas and D. Hartmann and B. Heger and B. Heinemann and A. Herrmann and J. Hobirk and F. Hofmeister and H. Hohen{\"o}cker and L. Horton and V. Igochine and D. Jacobi and M. Jakobi and F. Jenko and A. Kallenbach and O. Kardaun and M. Kaufmann and A. Keller and A. Kendl and Kim, \{J. W.\} and K. Kirov and R. Kochergov and H. Kollotzek and W. Kraus and K. Krieger and B. Kurzan and Lang, \{P. T.\} and P. Lauber and M. Laux and F. Leuterer and A. Lohs and A. Lorenz and C. Maggi and H. Maier and K. Mank and Manso, \{M. E.\} and M. Maraschek and Mast, \{K. F.\} and P. McCarthy and D. Meisel and H. Meister and F. Meo and R. Merkel and D. Merkl and V. Mertens and F. Monaco and A. M{\"u}ck and M{\"u}ller, \{H. W.\} and M. M{\"u}nich and H. Murmann and Na, \{Y. S.\} and G. Neu and R. Neu and J. Neuhauser and Noterdaeme, \{J. M.\} and I. Nunes and G. Pautasso and Peeters, \{A. G.\} and G. Pereverzev and S. Pinches and E. Poli and M. Proschek and R. Pugno and E. Quigley and G. Raupp and T. Ribeiro and R. Riedl and S. Riondato and V. Rohde and J. Roth and F. Ryter and S. Saarelma and W. Sandmann and S. Schade and Schilling, \{H. B.\} and W. Schneider and G. Schramm and S. Schweizer and B. Scott and U. Seidel and F. Serra and S. Sesnic and C. Sihler and A. Silva and E. Speth and A. St{\"a}bler and Steuer, \{K. H.\} and J. Stober and B. Streibl and E. Strumberger and W. Suttrop and A. Tabasso and A. Tanga and G. Tardini and C. Tichmann and W. Treutterer and M. Troppmann and P. Varela and O. Vollmer and D. Wagner and U. Wenzel and F. Wesner and R. Wolf and E. Wolfrum and E. W{\"u}rsching and Q. Yu and D. Zasche and T. Zehetbauer and Zehrfeld, \{H. P.\} and H. Zohm",

year = "2002",

month = dec,

doi = "10.1088/0741-3335/44/12b/306",

language = "English",

volume = "44",

pages = "B69--B83",

journal = "Plasma Physics and Controlled Fusion",

issn = "0741-3335",

publisher = "IOP Publishing Ltd.",

number = "12 B SPEC",

note = "29th European Physical Society Conference on Plasma Physics and Controlled Fusion ; Conference date: 17-06-2002 Through 21-06-2002",

}

Sips, ACC, Arslanbekov, R, Atanasiu, C, Becker, W, Becker, G, Behler, K, Behringer, K, Bergmann, A, Bilato, R, Bolshukhin, D, Borrass, K, Braams, B, Brambilla, M, Braun, F, Buhler, A, Conway, G, Coster, D, Drube, R, Dux, R, Egorov, S, Eich, T, Engelhardt, K, Fahrbach, HU, Fantz, U, Faugel, H, Foley, M, Fournier, KB, Franzen, P, Fuchs, JC, Gafert, J, Gantenbein, G, Gehre, O, Geier, A, Gernhardt, J, Gruber, O, Gude, A, Günter, S, Haas, G, Hartmann, D, Heger, B, Heinemann, B, Herrmann, A, Hobirk, J, Hofmeister, F, Hohenöcker, H, Horton, L, Igochine, V, Jacobi, D, Jakobi, M, Jenko, F, Kallenbach, A, Kardaun, O, Kaufmann, M, Keller, A, Kendl, A, Kim, JW, Kirov, K, Kochergov, R, Kollotzek, H, Kraus, W, Krieger, K, Kurzan, B, Lang, PT, Lauber, P, Laux, M, Leuterer, F, Lohs, A, Lorenz, A, Maggi, C, Maier, H, Mank, K, Manso, ME, Maraschek, M, Mast, KF, McCarthy, P, Meisel, D, Meister, H, Meo, F, Merkel, R, Merkl, D, Mertens, V, Monaco, F, Mück, A, Müller, HW, Münich, M, Murmann, H, Na, YS, Neu, G, Neu, R, Neuhauser, J, Noterdaeme, JM, Nunes, I, Pautasso, G, Peeters, AG, Pereverzev, G, Pinches, S, Poli, E, Proschek, M, Pugno, R, Quigley, E, Raupp, G, Ribeiro, T, Riedl, R, Riondato, S, Rohde, V, Roth, J, Ryter, F, Saarelma, S, Sandmann, W, Schade, S, Schilling, HB, Schneider, W, Schramm, G, Schweizer, S, Scott, B, Seidel, U, Serra, F, Sesnic, S, Sihler, C, Silva, A, Speth, E, Stäbler, A, Steuer, KH, Stober, J, Streibl, B, Strumberger, E, Suttrop, W, Tabasso, A, Tanga, A, Tardini, G, Tichmann, C, Treutterer, W, Troppmann, M, Varela, P, Vollmer, O, Wagner, D, Wenzel, U, Wesner, F, Wolf, R, Wolfrum, E, Würsching, E, Yu, Q, Zasche, D, Zehetbauer, T, Zehrfeld, HP & Zohm, H 2002, 'Steady state advanced scenarios at ASDEX Upgrade', Plasma Physics and Controlled Fusion, vol. 44, no. 12 B SPEC, pp. B69-B83. https://doi.org/10.1088/0741-3335/44/12b/306

TY - JOUR

T1 - Steady state advanced scenarios at ASDEX Upgrade

AU - Sips, A. C.C.

AU - Arslanbekov, R.

AU - Atanasiu, C.

AU - Becker, W.

AU - Becker, G.

AU - Behler, K.

AU - Behringer, K.

AU - Bergmann, A.

AU - Bilato, R.

AU - Bolshukhin, D.

AU - Borrass, K.

AU - Braams, B.

AU - Brambilla, M.

AU - Braun, F.

AU - Buhler, A.

AU - Conway, G.

AU - Coster, D.

AU - Drube, R.

AU - Dux, R.

AU - Egorov, S.

AU - Eich, T.

AU - Engelhardt, K.

AU - Fahrbach, H. U.

AU - Fantz, U.

AU - Faugel, H.

AU - Foley, M.

AU - Fournier, K. B.

AU - Franzen, P.

AU - Fuchs, J. C.

AU - Gafert, J.

AU - Gantenbein, G.

AU - Gehre, O.

AU - Geier, A.

AU - Gernhardt, J.

AU - Gruber, O.

AU - Gude, A.

AU - Günter, S.

AU - Haas, G.

AU - Hartmann, D.

AU - Heger, B.

AU - Heinemann, B.

AU - Herrmann, A.

AU - Hobirk, J.

AU - Hofmeister, F.

AU - Hohenöcker, H.

AU - Horton, L.

AU - Igochine, V.

AU - Jacobi, D.

AU - Jakobi, M.

AU - Jenko, F.

AU - Kallenbach, A.

AU - Kardaun, O.

AU - Kaufmann, M.

AU - Keller, A.

AU - Kendl, A.

AU - Kim, J. W.

AU - Kirov, K.

AU - Kochergov, R.

AU - Kollotzek, H.

AU - Kraus, W.

AU - Krieger, K.

AU - Kurzan, B.

AU - Lang, P. T.

AU - Lauber, P.

AU - Laux, M.

AU - Leuterer, F.

AU - Lohs, A.

AU - Lorenz, A.

AU - Maggi, C.

AU - Maier, H.

AU - Mank, K.

AU - Manso, M. E.

AU - Maraschek, M.

AU - Mast, K. F.

AU - McCarthy, P.

AU - Meisel, D.

AU - Meister, H.

AU - Meo, F.

AU - Merkel, R.

AU - Merkl, D.

AU - Mertens, V.

AU - Monaco, F.

AU - Mück, A.

AU - Müller, H. W.

AU - Münich, M.

AU - Murmann, H.

AU - Na, Y. S.

AU - Neu, G.

AU - Neu, R.

AU - Neuhauser, J.

AU - Noterdaeme, J. M.

AU - Nunes, I.

AU - Pautasso, G.

AU - Peeters, A. G.

AU - Pereverzev, G.

AU - Pinches, S.

AU - Poli, E.

AU - Proschek, M.

AU - Pugno, R.

AU - Quigley, E.

AU - Raupp, G.

AU - Ribeiro, T.

AU - Riedl, R.

AU - Riondato, S.

AU - Rohde, V.

AU - Roth, J.

AU - Ryter, F.

AU - Saarelma, S.

AU - Sandmann, W.

AU - Schade, S.

AU - Schilling, H. B.

AU - Schneider, W.

AU - Schramm, G.

AU - Schweizer, S.

AU - Scott, B.

AU - Seidel, U.

AU - Serra, F.

AU - Sesnic, S.

AU - Sihler, C.

AU - Silva, A.

AU - Speth, E.

AU - Stäbler, A.

AU - Steuer, K. H.

AU - Stober, J.

AU - Streibl, B.

AU - Strumberger, E.

AU - Suttrop, W.

AU - Tabasso, A.

AU - Tanga, A.

AU - Tardini, G.

AU - Tichmann, C.

AU - Treutterer, W.

AU - Troppmann, M.

AU - Varela, P.

AU - Vollmer, O.

AU - Wagner, D.

AU - Wenzel, U.

AU - Wesner, F.

AU - Wolf, R.

AU - Wolfrum, E.

AU - Würsching, E.

AU - Yu, Q.

AU - Zasche, D.

AU - Zehetbauer, T.

AU - Zehrfeld, H. P.

AU - Zohm, H.

PY - 2002/12

Y1 - 2002/12

N2 - Recent experiments at ASDEX Upgrade have achieved advanced scenarios with high fin (>3) and confinement enhancement over ITER98(y, 2) scaling, HH98y2 = 1.1-1.5, in steady state. These discharges have been obtained in a modified divertor configuration for ASDEX Upgrade, allowing operation at higher triangularity, and with a changed neutral beam injection (NBI) system, for a more tangential, off-axis beam deposition. The figure of merit, βNHITER89-P, reaches up to 7.5 for several seconds in plasmas approaching stationary conditions. These advanced tokamak discharges have low magnetic shear in the centre, with q on-axis near 1, and edge safety factor, q95 in the range 3.3-4.5. This q-profile is sustained by the bootstrap current, NBI-driven current and fishbone activity in the core. The off-axis heating leads to a strong peaking of the density profile and impurity accumulation in the core. This can be avoided by adding some central heating from ion cyclotron resonance heating or electron cyclotron resonance heating, since the temperature profiles are stiff in this advanced scenario (no internal transport barrier). Using a combination of NBI and gas fuelling line, average densities up to 80-90% of the Greenwald density are achieved, maintaining good confinement. The best integrated results in terms of confinement, stability and ability to operate at high density are obtained in highly shaped configurations, near double null, with δ = 0.43. At the highest densities, a strong reduction of the edge localized mode activity similar to type II activity is observed, providing a steady power load on the divertor, in the range of 6 MW m-2, despite the high input power used (> 10 MW).

AB - Recent experiments at ASDEX Upgrade have achieved advanced scenarios with high fin (>3) and confinement enhancement over ITER98(y, 2) scaling, HH98y2 = 1.1-1.5, in steady state. These discharges have been obtained in a modified divertor configuration for ASDEX Upgrade, allowing operation at higher triangularity, and with a changed neutral beam injection (NBI) system, for a more tangential, off-axis beam deposition. The figure of merit, βNHITER89-P, reaches up to 7.5 for several seconds in plasmas approaching stationary conditions. These advanced tokamak discharges have low magnetic shear in the centre, with q on-axis near 1, and edge safety factor, q95 in the range 3.3-4.5. This q-profile is sustained by the bootstrap current, NBI-driven current and fishbone activity in the core. The off-axis heating leads to a strong peaking of the density profile and impurity accumulation in the core. This can be avoided by adding some central heating from ion cyclotron resonance heating or electron cyclotron resonance heating, since the temperature profiles are stiff in this advanced scenario (no internal transport barrier). Using a combination of NBI and gas fuelling line, average densities up to 80-90% of the Greenwald density are achieved, maintaining good confinement. The best integrated results in terms of confinement, stability and ability to operate at high density are obtained in highly shaped configurations, near double null, with δ = 0.43. At the highest densities, a strong reduction of the edge localized mode activity similar to type II activity is observed, providing a steady power load on the divertor, in the range of 6 MW m-2, despite the high input power used (> 10 MW).

UR - https://www.scopus.com/pages/publications/0036947635

U2 - 10.1088/0741-3335/44/12b/306

DO - 10.1088/0741-3335/44/12b/306

M3 - Conference article

AN - SCOPUS:0036947635

SN - 0741-3335

VL - 44

SP - B69-B83

JO - Plasma Physics and Controlled Fusion

JF - Plasma Physics and Controlled Fusion

IS - 12 B SPEC

T2 - 29th European Physical Society Conference on Plasma Physics and Controlled Fusion

Y2 - 17 June 2002 through 21 June 2002

ER -

Steady state advanced scenarios at ASDEX Upgrade

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