论文信息 - H-mode pedestal, ELM and power threshold studies in NSTX - 字舞流文

H-mode pedestal, ELM and power threshold studies in NSTX

H-mode operation plays a crucial role in National Spherical Torus Experiment (NSTX) research, allowing higher beta limits due to reduced plasma pressure peaking, and long pulse operation due to high bootstrap current fraction. Here, new results are presented in the areas of edge localized modes (ELMs), H-mode pedestal physics and power threshold studies. ELMs of several types as reported by higher aspect ratio tokamaks have been observed: (1) large, Type I ELMs, (2) intermediate-sized Type III ELMs and (3) tiny ELMs. Many high performance discharges in NSTX have the tiny ELMs (recently termed Type V), which have some differences as compared with small-magnitude ELM types in the published literature. A divertor multifaceted axisymmetric radiation from the edge (MARFE) on the inboard leg provides an effective light source to examine the effect of the ELMs on the divertor plasma; it is clear that only the large ELMs burn through the MARFE. The time difference between observation of the ELM flux at the outer and inner targets is substantially longer for the smallest ELMs as compared with the large ELMs. In addition, the visible light patterns show ‘finger-like’ striations during the tiny ELMs. H-mode pedestal studies have commenced, with the observation that the pedestal contains between 25% and 33% of the total stored energy, and the NSTX pedestal energy agrees reasonably well with a recent international multi-machine scaling. A power threshold identity experiment between NSTX and the Mega-Amp Spherical Tokamak shows comparable loss power at the L–H transition in balanced double-null discharges. Both machines require more power for the L–H transition as the balance is shifted toward lower-single null. High-field side gas fuelling enables more reliable H-mode access in NSTX, but does not always lead to a lower power threshold, e.g. with a reduction of the duration of early heating.

E. D. Fredrickson | R. E. Bell | Henry W. Kugel | Rajesh Maingi | Dan Stutman | D. W. Johnson | D. A. Gates | S. A. Sabbagh | A. L. Roquemore | Benoit P. Leblanc | Stanley M. Kaye | Roger Raman | H. Meyer | Kevin Lee Tritz | Jonathan Menard | Stewart J. Zweben | Theodore Mathias Biewer | R. J. Maqueda | Tobin Leo Munsat | Nobuhiro Nishino | Robert Kaita | Vlad Soukhanovskii | D. W. Mueller | K. Tritz | D. Stutman | R. Bell | B. Leblanc | D. Gates | H. Kugel | R. Kaita | A. Roquemore | S. Zweben | E. Fredrickson | S. Sabbagh | M. Bell | S. Kaye | J. Boedo | C. Bush | R. Maingi | D. Mueller | R. Raman | V. Soukhanovskii | T. Stevenson | N. Nishino | T. Biewer | R. Maqueda | H. Meyer | T. Munsat | Michael G. Bell | Charles E. Bush | Jose Armando Boedo | T. Stevenson | J. Menard | D.W. Johnson | B. LeBlanc | D. Johnson

[1] T. Evans,et al. Experimental Signatures of Homoclinic Tangles in Poloidally Diverted Tokamaks , 2005 .

[2] B. Leblanc,et al. Divertor regimes in NSTX , 2005 .

[3] S. Mahajan,et al. A theory for the pressure pedestal in high (H) mode tokamak discharges , 2005 .

[4] K. Tritz,et al. Measurement of Edge Localized Mode using Fast Camera in NSTX , 2005 .

[5] K. Burrell,et al. ELM-Induced Plasma Transport in the DIII-D SOL , 2004 .

[6] A. Hubbard,et al. Pedestal characteristics in JFT-2M HRS H-mode plasma , 2004 .

[7] V. Soukhanovskii,et al. NSTX tangential divertor camera , 2004 .

[8] K. Tritz,et al. ELMs and the H-mode pedestal in NSTX , 2004 .

[9] A. Kirk,et al. Spatial and temporal structure of edge-localized modes. , 2004, Physical review letters.

[10] K. Tritz,et al. Observation of a high performance operating regime with small edge-localized modes in the National Spherical Torus Experiment , 2004 .

[11] P. Helander,et al. The influence of gas fuelling location on H-mode access in the MAST spherical tokamak , 2004 .

[12] C. Challis,et al. Formation of transport barriers in the MAST spherical tokamak , 2004 .

[13] M. G. Bell,et al. Effect of gas fuelling location on H-mode access in NSTX , 2004 .

[14] S. S. Medley,et al. Confinement studies of auxiliary heated NSTX plasmas , 2004 .

[15] B. Leblanc,et al. High-speed imaging of edge turbulence in NSTX , 2004 .

[16] T. Eich,et al. Nonaxisymmetric energy deposition pattern on ASDEX upgrade divertor target plates during type-I edge-localized modes. , 2003, Physical review letters.

[17] T. Fülöp,et al. Controlling Edge Plasma Rotation Through Poloidally Localized Refueling , 2003 .

[18] H. Ogawa,et al. Observation of High Recycling Steady H-mode edge and compatibility with improved core confinement mode on JFT-2M , 2003 .

[19] B. Leblanc,et al. Low- to high-confinement mode transitions in the National Spherical Torus Experiment , 2003 .

[20] E. D. Fredrickson,et al. H-mode research in NSTX , 2003 .

[21] J. G. Cordey,et al. A two-term model of the confinement in Elmy H-modes using the global confinement and pedestal databases , 2003 .

[22] K. C. Lee,et al. H-mode threshold and dynamics in the National Spherical Torus Experiment , 2003 .

[23] K. Fournier,et al. Integrated impurity diagnostic package for magnetic fusion experiments , 2003 .

[24] V. Soukhanovskii,et al. High Resolution Spectroscopic Diagnostic for Divertor and Scrape-off Layer Neutral and Impurity Emission Measurements in the National Spherical Torus Experiment , 2003 .

[25] Ph. Ghendrih,et al. Patterns of ELM impacts on the JET wall components , 2003 .

[26] L. Horton,et al. ELM energy and particle losses and their extrapolation to burning plasma experiments , 2003 .

[27] Nstx Team,et al. First Results with the NSTX Fast Divertor Camera , 2002 .

[28] J. G. Cordey,et al. Development of a two-term model for the confinement in ELMy H-modes using the global confinement and pedestal databases , 2002 .

[29] Y-K.M. Peng,et al. Evolution and termination of H-modes in NSTX , 2002 .

[30] G. F. Counsell,et al. H-mode plasmas in the MAST spherical tokamak , 2002 .

[31] Y-K.M. Peng,et al. Characteristics of the first H-mode discharges in the national spherical torus experiment. , 2002, Physical review letters.

[32] L. L. Lao,et al. Equilibrium properties of spherical torus plasmas in NSTX , 2001 .

[33] W. Treutterer,et al. Type II ELMy H modes on ASDEX Upgrade with good confinement at high density , 2001 .

[34] G. Staebler,et al. Quiescent double barrier regime in the DIII-D tokamak. , 2001, Physical review letters.

[35] L. Lao,et al. Quiescent double barrier high-confinement mode plasmas in the DIII-D tokamak , 2001 .

[36] T. Osborne,et al. Tolerable ELMs at high density in DIII-D , 2001 .

[37] H. Kugel,et al. Edge turbulence measurements in NSTX by gas puff imaging , 2001 .

[38] Ronald H. Cohen,et al. Low-to-high confinement transition simulations in divertor geometry , 2000 .

[39] M. Viola,et al. Exploration of spherical torus physics in the NSTX device , 2000 .

[40] D. J. Campbell,et al. Chapter 1: Overview and summary , 1999 .

[41] R. J. Groebner,et al. Critical edge parameters for H-mode transition in DIII-D , 1997 .

[42] P. T. Bonoli,et al. Radiofrequency-heated enhanced confinement modes in the Alcator C-Mod tokamak , 1997 .

[43] W. A. Peebles,et al. Modifications in turbulence and edge electric fields at the L–H transition in the DIII‐D tokamak , 1991 .

[44] L. Lao,et al. Plasma shaping, edge ballooning stability and ELM behaviour in DIII-D , 1990 .

[45] L. Lao,et al. Reconstruction of current profile parameters and plasma shapes in tokamaks , 1985 .

[46] S. Wolfe,et al. Marfe: an edge plasma phenomenon , 1984 .

[47] M. Nagami,et al. Observation of cold, high-density plasma near the Doublet III limiter , 1982 .

[48] J. W. Connor,et al. Shear, periodicity, and plasma ballooning modes , 1978 .