论文信息 - Properties of thermal decay and radiative collapse of NBI heated plasmas on LHD - 字舞流文

Properties of thermal decay and radiative collapse of NBI heated plasmas on LHD

In LHD discharges, the NBI heated plasmas are terminated in two ways: (a) thermal decay (TD) after the termination of NBI and (b) radiative collapse (RC) during the NBI heating. The basic characteristics of the TD and RC discharges are compared. It is found that the decay and collapse of the plasma are mainly governed by the heating power and the plasma density. The critical density c for the collapse of RC plasmas is similar to the scaling laws obtained in other helical devices, i.e. c∝(PB/V)0.5, where P, B and V denote heating power, magnetic field and plasma volume, respectively. Moreover, measurements using multichannel bolometric diagnostics indicate that the total radiation profiles in TD and RC plasmas are usually inboard-outboard symmetric and asymmetric, respectively, at the end of the discharge. In RC discharges, the total radiation profile develops in several phases. Before the onset of the thermal instability (TI), the radiation profile is rather symmetric, while after that, the radiation profile evolves from being symmetric in the initial period towards being asymmetric eventually with high radiation on the inboard side. Corresponding variations are shown in the time evolutions of the density and temperature profiles, and a substantial contraction of the plasma column is observed immediately after TI onset. The spatial and temporal coincidence of the asymmetries in the radiation, density and temperature is similar to that observed with multifaceted asymmetric radiation from the edge (MARFE) in tokamaks. But, unlike MARFEs, the asymmetric radiation (AR) in LHD is rather transient since it appears just before the end of RC discharges. The underlying cause for the development of radiation asymmetry was investigated and compared with existing instability models. The result suggests that the high inboard radiation is a manifestation of an enhanced local thermal instability, and the AR results from asymmetric developments of TI on the inboard-outboard sides during the final stage of RC discharges.

Masaki Osakabe | N. Ohyabu | Hiroshi Yamada | Osamu Kaneko | Tokihiko Tokuzawa | Hiroshi Idei | Shin Kubo | Motoshi Goto | Kazuo Kawahata | J. Miyazawa | K. Narihara | S. Sudo | Satoru Sakakibara | Katsuyoshi Tsumori | Kiyohiko Nishimura | Katsunori Ikeda | K. Kawahata | Kokichi Tanaka | K. Watanabe | N. Ohyabu | J. Miyazawa | M. Goto | S. Morita | B. Peterson | S. Sakakibara | T. Tokuzawa | K. Narihara | H. Yamada | H. Idei | O. Kaneko | S. Kubo | K. Nishimura | M. Osakabe | K. Tsumori | S. Sudo | Y. Xu | A. Kostrioukov | Y. Xu | Byron J. Peterson | K. Y. Watanabe | K. Ikeda | S. Morita | Kokichi Tanaka | A. Kostrioukov | K. Komori | K. Komori

[1] K. Kawahata,et al. In situ calibration of neutral beam port-through power and estimation of neutral beam deposition on LHD , 2001 .

[2] C. Andelfinger,et al. A Low Noise Highly Integrated Bolometer Array for Absolute Measurement of VUV and Soft X Radiation , 1991 .

[3] W. Stacey. Density limits in tokamaks , 1997 .

[4] G. Pereverzev,et al. Models for the development of the discharge in a tokamak , 1983 .

[5] J. P. Goedbloed,et al. Marfes : a magnetohydrodynamic stability study of two-dimensional tokamak equilibria , 1997 .

[6] Murakami,et al. Energy confinement time and heat transport in initial neutral beam heated plasmas on the large helical device , 2000, Physical review letters.

[7] Georg Kühner,et al. Radiation measurements and modeling of the density limit on the W7-AS stellarator , 1999 .

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

[9] H. Yamada,et al. Effect of carbon divertor plates on impurities, Zeff and density limit in large helical device , 2001 .

[10] J. C. Whitson,et al. Steepest‐descent moment method for three‐dimensional magnetohydrodynamic equilibria , 1983 .

[11] N. Ohyabu. Density limit in tokamaks , 1979 .

[12] T. Hender,et al. An extended treatment of marfe stability (plasma) , 1993 .

[13] Y. Takeiri,et al. Scalings of energy confinement and density limit in stellarator/heliotron devices , 1990 .

[14] James F. Drake,et al. Marfes: Radiative condensation in tokamak edge plasma , 1987 .

[15] J. L. Cecchi,et al. PDX Divertor operation , 1980 .

[16] B. Wan,et al. Improved confinement mode induced by the MARFE on the HT-7 superconducting tokamak , 1999 .

[17] K. Tanaka,et al. The effect of divertor tile material on radiation profiles in LHD , 2001 .

[18] F. C. Schüller,et al. Influence of Recycling on the Density Limit in TEXTOR-94 , 1998 .

[19] W. Stacey. Thermal stability of the tokamak plasma edge , 1997 .

[20] D. Post,et al. Radiation rates for low Z impurities in edge plasmas , 1995, plasm-ph/9506001.

[21] H. Takeuchi,et al. MARFE phenomena on neutral beam heated JT-60 plasmas , 1990 .

[22] F. C. Schüller,et al. Localized recycling as a trigger of MARFE , 1999 .

[23] K. F. Mast,et al. Disruptions in JET , 1989 .

[24] Kozo Yamazaki,et al. Initial physics achievements of large helical device experiments , 1999 .

[25] L. Giannone,et al. Physics of the density limit in the W7-AS stellarator , 2000 .

[26] V. Erckmann,et al. H-mode of W7-AS stellarator , 1994 .

[27] H. Wobig,et al. On Radiative Density Limits and Anomalous Transport in Stellarators , 2000 .

[28] D. Post. A review of recent developments in atomic processes for divertors and edge plasmas , 1995, plasm-ph/9506003.

[29] Role of core radiation during slow oscillations in LHD , 2001 .

[30] Douglass E. Post,et al. Steady-state radiative cooling rates for low-density, high-temperature plasmas , 1977 .

[31] G. Waidmann,et al. Density limits and evolution of disruptions in ohmic TEXTOR plasmas , 1992 .

[32] Masaki Osakabe,et al. Multifaceted asymmetric radiation from the edge-like asymmetric radiative collapse of density limited plasmas in the Large Helical Device , 2001 .

[33] Y. Andrew,et al. Sensitivity of calculated neutral helium line intensities and their ratios to uncertainties in excitation rate coefficients , 2000 .

[34] K. Kawahata,et al. Far infrared laser interferometer system on the Large Helical Device , 1999 .

[35] W. Schneider,et al. Thermal instabilities and poloidal asymmetries in the tokamak edge plasma , 1986 .

[36] Hiroshi Hayashi,et al. Design and performance of the Thomson scattering diagnostic on LHD , 2001 .

[37] K. Itoh,et al. Detached and attached plasma in stellarators , 1988 .

[38] A. Tanga,et al. The regime of enhanced particle recycling in high density tokamak discharges in the Frascati torus , 1982 .

[39] K. Kawahata,et al. Plasma characteristics of long-pulse discharges heated by neutral beam injection in the Large Helical Device , 2000 .

[40] Bruce Lipschultz,et al. Review of MARFE phenomena in tokamaks , 1987 .

[41] C. Bush,et al. Phenomenology of MARFEs in TFTR , 1987 .

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

[43] F. C. Schüller,et al. Density limits in TEXTOR-94 auxiliary heated discharges , 1999 .

[44] M. Hughes,et al. A study of the effect of impurity radiation from the peripheral plasma of a tokamak reactor , 1981 .