论文信息 - Current profile, MHD activity and transport properties of optimized shear plasmas in JET - 字舞流文

Current profile, MHD activity and transport properties of optimized shear plasmas in JET

High fusion performance has been achieved in optimized shear discharges in JET with the early appearance of internal transport barriers (ITBs) in the high power phase in both DD and DT plasmas. An ITB has been produced in a large variety of conditions, including LHCD only, ICRH only, NBI only and NBI + ICRH with LHCD preheat. An ITB may coexist with the edge barrier. The high pressure gradient produced by ICRH combined with high power NBI heating starting in a low density plasma with q(0) ≈ 1.5-2 is the main prerequisite for an efficient ITB in high performance discharges. Strong coupling between q profiles, MHD activity, energy confinement and fusion yield has been observed. The transition from L to H mode can be triggered by MHD events. The transition is accompanied by significant momentary changes in the density fluctuation spectrum in the peripheral plasma. The ITB may persist for some time in both ELM-free and ELMy H mode.

C. D. Challis | X. Litaudon | David Ward | C. Gormezano | A. C. C. Sips | D. V. Bartlett | G. T. A. Huysmans | F. X. Söldner | B. Alper | P. Smeulders | B.J.D. Tubbing | V. V. Parail | G. A. Cottrell | N. Deliyanakis | M. von Hellermann | G. D. Conway | V. Parail | A. Sips | B. Alper | C. Challis | G. Huysmans | X. Litaudon | C. Gormezano | Y. Baranov | G. Conway | M. Hellermann | D. Ward | P. Smeulders | G. Cottrell | N. Deliyanakis | F. Söldner | B. Tubbing | D. Bartlett | Yu.F. Baranov

[1] S. Coda,et al. Beyond paradigm: Turbulence, transport, and the origin of the radial electric field in low to high confinement mode transitions in the DIII-D tokamak , 1995 .

[2] Giuseppe Gorini,et al. Electron thermal transport in RTP: filaments, barriers and bifurcations , 1997 .

[3] G. Hammett,et al. Gyrofluid simulations of turbulence suppression in reversed-shear experiments on the Tokamak Fusion Test Reactor , 1997 .

[4] F. X. Söldner,et al. Shear optimization experiments with current profile control on JET , 1997 .

[5] A. T. Ramsey,et al. Simulations of deuterium-tritium experiments in TFTR , 1992 .

[6] F. G. Rimini,et al. Isotope scaling of the H mode power threshold on JET , 1999 .

[7] Manickam,et al. Improved plasma performance in tokamaks with negative magnetic shear. , 1994, Physical review letters.

[8] Lao,et al. Enhanced confinement and stability in DIII-D discharges with reversed magnetic shear. , 1995, Physical review letters.

[9] T. Luce,et al. INTERNAL TRANSPORT BARRIERS IN JET DEUTERIUM-TRITIUM PLASMAS , 1998 .

[10] E. J. Synakowski,et al. Formation and structure of internal and edge transport barriers , 1998 .

[11] E. Synakowski,et al. Core poloidal rotation and internal transport barrier formation in TFTR , 1998 .

[12] D. McCune,et al. New techniques for calculating heat and particle source rates due to neutral beam injection in axisymmetric tokamaks , 1981 .

[13] G. Rewoldt,et al. Toroidal microinstability studies of high‐temperature tokamaks , 1990 .

[14] S. Hirshman. Neoclassical current in a toroidally‐confined multispecies plasma , 1977 .

[15] L. L. Lao,et al. Equilibrium analysis of current profiles in tokamaks , 1990 .

[16] David E. Newman,et al. Self-similarity of the plasma edge fluctuations , 1998 .

[17] Tsuji,et al. Internal transport barrier on q=3 surface and poloidal plasma spin up in JT-60U high- beta p discharges. , 1994, Physical review letters.

[18] Liu Chen,et al. Theory of magnetohydrodynamic instabilities excited by energetic particles in tokamaks , 1994 .

[19] E. D. Fredrickson,et al. Improved confinement with reversed magnetic shear in TFTR. , 1995 .

[20] R. J. Hawryluk,et al. Neoclassical conductivity of a tokamak plasma , 1977 .

[21] E. J. Strait,et al. Operation at high performance in optimized shear plasmas in JET , 1998 .

[22] M. Rosenbluth,et al. Toroidal ion‐pressure‐gradient‐driven drift instabilities and transport revisited , 1989 .

[23] Tadashi Sekiguchi,et al. Plasma Physics and Controlled Nuclear Fusion Research , 1987 .

[24] F. Imbeaux,et al. Electron and ion internal transport barriers in Tore Supra and JET , 1999 .

[25] E. J. Strait,et al. Approach to steady state high performance in DD and DT plasmas with optimized shear in JET , 1999 .

[26] H. Shirai,et al. Internal transport barrier with improved confinement in the JT-60U tokamak , 1996 .

[27] W. Heidbrink. Beam-driven chirping instability in DIII-D , 1995 .

[28] G. M. Staebler,et al. Theory of internal and edge transport barriers , 1998 .

[29] K. H. Burrell,et al. Flow shear induced fluctuation suppression in finite aspect ratio shaped tokamak plasma , 1995 .

[30] G. Magyar,et al. Plasma diagnostics on large tokamaks , 1988 .

[31] Course,et al. Basic physical processes of toroidal fusion plasmas : proceedings of the course and workshop held at Villa Monastero - Varenna, Italy, August 26-September 3, 1985 , 1986 .

[32] M. Wakatani,et al. Negative shear effect on toroidal ion temperature gradient mode , 1995 .

[33] Hiroshi Shirai,et al. Study of internal transport barriers by comparison of reversed shear and high- discharges in JT-60U , 1998 .

[34] Murakami,et al. Energy Transport in Tokamak Plasmas with Central Current Density Control Using Fast Waves. , 1996, Physical review letters.