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

Yuhong Xu; B. J. Peterson; S. Sudo; T. Tokuzawa; K. Narihara; M. Osakabe; S. Morita; M. Goto; S. Sakakibara; K. Tanaka; K. Kawahata; K. Tsumori; K. Ikeda; S. Kubo; H. Idei; J. Miyazawa; K. Y. Watanabe; K. Nishimura; A. Kostrioukov; H. Yamada; O. Kaneko; N. Ohyabu; K. Komori

doi:10.1088/0029-5515/42/5/312

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

Yuhong Xu, B. J. Peterson, S. Sudo, T. Tokuzawa, K. Narihara, M. Osakabe, S. Morita, M. Goto, S. Sakakibara, K. Tanaka, K. Kawahata, K. Tsumori, K. Ikeda, S. Kubo, H. Idei, J. Miyazawa, K. Y. Watanabe, K. Nishimura, A. Kostrioukov, H. YamadaO. Kaneko, N. Ohyabu, K. Komori

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Abstract

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 n̄_c for the collapse of RC plasmas is similar to the scaling laws obtained in other helical devices, i.e. n̄_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.

Original language	English
Pages (from-to)	601-613
Number of pages	13
Journal	Nuclear Fusion
Volume	42
Issue number	5
DOIs	https://doi.org/10.1088/0029-5515/42/5/312
Publication status	Published - May 1 2002
Externally published	Yes

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Condensed Matter Physics

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10.1088/0029-5515/42/5/312

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Xu, Y., Peterson, B. J., Sudo, S., Tokuzawa, T., Narihara, K., Osakabe, M., Morita, S., Goto, M., Sakakibara, S., Tanaka, K., Kawahata, K., Tsumori, K., Ikeda, K., Kubo, S., Idei, H., Miyazawa, J., Watanabe, K. Y., Nishimura, K., Kostrioukov, A., ... Komori, K. (2002). Properties of thermal decay and radiative collapse of NBI heated plasmas on LHD. Nuclear Fusion, 42(5), 601-613. https://doi.org/10.1088/0029-5515/42/5/312

Xu, Y, Peterson, BJ, Sudo, S, Tokuzawa, T, Narihara, K, Osakabe, M, Morita, S, Goto, M, Sakakibara, S, Tanaka, K, Kawahata, K, Tsumori, K, Ikeda, K, Kubo, S, Idei, H, Miyazawa, J, Watanabe, KY, Nishimura, K, Kostrioukov, A, Yamada, H, Kaneko, O, Ohyabu, N & Komori, K 2002, 'Properties of thermal decay and radiative collapse of NBI heated plasmas on LHD', Nuclear Fusion, vol. 42, no. 5, pp. 601-613. https://doi.org/10.1088/0029-5515/42/5/312

@article{5064595f13d44f8fa409af8b71b5a5ad,

title = "Properties of thermal decay and radiative collapse of NBI heated plasmas on LHD",

abstract = "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 {\=n}c for the collapse of RC plasmas is similar to the scaling laws obtained in other helical devices, i.e. {\=n}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.",

author = "Yuhong Xu and Peterson, {B. J.} and S. Sudo and T. Tokuzawa and K. Narihara and M. Osakabe and S. Morita and M. Goto and S. Sakakibara and K. Tanaka and K. Kawahata and K. Tsumori and K. Ikeda and S. Kubo and H. Idei and J. Miyazawa and Watanabe, {K. Y.} and K. Nishimura and A. Kostrioukov and H. Yamada and O. Kaneko and N. Ohyabu and K. Komori",

year = "2002",

month = may,

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doi = "10.1088/0029-5515/42/5/312",

language = "English",

volume = "42",

pages = "601--613",

journal = "Nuclear Fusion",

issn = "0029-5515",

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T1 - Properties of thermal decay and radiative collapse of NBI heated plasmas on LHD

AU - Xu, Yuhong

AU - Peterson, B. J.

AU - Sudo, S.

AU - Tokuzawa, T.

AU - Narihara, K.

AU - Osakabe, M.

AU - Morita, S.

AU - Goto, M.

AU - Sakakibara, S.

AU - Tanaka, K.

AU - Kawahata, K.

AU - Tsumori, K.

AU - Ikeda, K.

AU - Kubo, S.

AU - Idei, H.

AU - Miyazawa, J.

AU - Watanabe, K. Y.

AU - Nishimura, K.

AU - Kostrioukov, A.

AU - Yamada, H.

AU - Kaneko, O.

AU - Ohyabu, N.

AU - Komori, K.

PY - 2002/5/1

Y1 - 2002/5/1

N2 - 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 n̄c for the collapse of RC plasmas is similar to the scaling laws obtained in other helical devices, i.e. n̄c ∝ (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.

AB - 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 n̄c for the collapse of RC plasmas is similar to the scaling laws obtained in other helical devices, i.e. n̄c ∝ (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.

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VL - 42

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EP - 613

JO - Nuclear Fusion

JF - Nuclear Fusion

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ER -

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

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