Recent advance progress of HL-3 experiments

X. R. Duan; M. Xu; W. L. Zhong; X. Q. Ji; W. Chen; Z. B. Shi; X. L. Liu; B. Lu; B. Li; Y. Q. Wang; J. Q. Li; G. Y. Zheng; Yong Liu; Q. W. Yang; L. W. Yan; L. J. Cai; Q. Li; Y. Liu; X. Y. Bai; Z. Cao; X. Chen; H. T. Chen; Y. H. Chen; G. Q. Dong; H. L. Du; D. M. Fan; J. M. Gao; S. F. Geng; G. Z. Hao; H. M. He; M. Huang; M. Jiang; R. Ke; A. S. Liang; J. X. Li; Qing Li; Yongge Li; L. C. Li; H. J. Li; W. B. Li; D. Q. Liu; T. Long; L. F. Lu; L. Nie; P. W. Shi; J. F. Peng; A. P. Sun; T. F. Sun; R. H. Tong; H. L. Wei; S. Wang; G. L. Xiao; X. P. Xiao; L. Xue; H. B. Xu; Z. Y. Yang; D. L. Yu; L. M. Yu; Y. P. Zhang; X. Zheng; L. Zhang; Y. Zhang; F. Zhang; X. L. Zhang; J. F. Artaud; L. Chen; L. Delpech; A. Ekedahl; P. H. Diamond; Y. H. Ding; J. Garcia; Z. Gao; X. Y. Gong; Z. B. Guo; T. G. Hoang; M. Isobe; Y. Q. Liu; D. Mazon; S. G.R. Mckee; S. Morita; Y. Peysson; Z. Y. Qiu; Y. Ren; R. Sharples; G. R. Tynan; X. G. Wang; Z. X. Wang; Y. H. Xu; Z. Yan; G. Zhuang; F. Zonca; X. L. Zou

doi:10.1088/1741-4326/ad6e9e

Recent advance progress of HL-3 experiments

X. R. Duan
, M. Xu
, W. L. Zhong
, X. Q. Ji
, W. Chen
, Z. B. Shi
, X. L. Liu
, B. Lu
, B. Li
, Y. Q. Wang
, J. Q. Li
, G. Y. Zheng
, Yong Liu
, Q. W. Yang
, L. W. Yan
, L. J. Cai
, Q. Li
, Y. Liu
, X. Y. Bai
, Z. Cao

X. Chen, H. T. Chen, Y. H. Chen, G. Q. Dong, H. L. Du, D. M. Fan, J. M. Gao, S. F. Geng, G. Z. Hao, H. M. He, M. Huang, M. Jiang, R. Ke, A. S. Liang, J. X. Li, Qing Li, Yongge Li, L. C. Li, H. J. Li, W. B. Li, D. Q. Liu, T. Long, L. F. Lu, L. Nie, P. W. Shi, J. F. Peng, A. P. Sun, T. F. Sun, R. H. Tong, H. L. Wei, S. Wang, G. L. Xiao, X. P. Xiao, L. Xue, H. B. Xu, Z. Y. Yang, D. L. Yu, L. M. Yu, Y. P. Zhang, X. Zheng, L. Zhang, Y. Zhang, F. Zhang, X. L. Zhang, J. F. Artaud, L. Chen, L. Delpech, A. Ekedahl, P. H. Diamond, Y. H. Ding, J. Garcia, Z. Gao, X. Y. Gong, Z. B. Guo, T. G. Hoang, M. Isobe, Y. Q. Liu, D. Mazon, S. G.R. Mckee, S. Morita, Y. Peysson, Z. Y. Qiu, Y. Ren, R. Sharples, G. R. Tynan, X. G. Wang, Z. X. Wang, Y. H. Xu, Z. Yan, G. Zhuang, F. Zonca, X. L. Zou

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Research output: Contribution to journal › Article › peer-review

27 Scopus citations

Abstract

Since the first plasma realized in 2020, a series of key systems on HL-3 (known as HL-2M before) tokamak have been equipped/upgraded, including in-vessel components (the first wall, lower divertor, and toroidal cryogenic/water-cooling/baking/glow discharge systems, etc.), auxiliary heating system of 11 MW, and 28 diagnostic systems (to measure the plasma density electron temperature, radiation, magnetic field, etc.). Magnet field systems were commissioned firstly for divertor plasma discharges. During the 2nd experimental campaign of HL-3 tokamak, several great progresses have been achieved. Firstly, the successful operation with plasma current larger than 1 MA was achieved under a divertor configuration. Secondly, the advanced divertor concept with two distinct snowflake configurations was realized. It is found that the distribution of ion saturation current and heat flux on bottom plate becomes wide due to magnetic surface expansion, demonstrating the advantage of such configuration in the heat flux mitigation. In addition, using the combination of NBI, ECRH and LHCD, the standard sawtoothing high confinement mode of megampere plasma was firstly accessed on the HL-3. The successful commissioning of HL-3 is beneficial for the initial operation of ITER.

Original language	English (US)
Article number	112021
Journal	Nuclear Fusion
Volume	64
Issue number	11
DOIs	https://doi.org/10.1088/1741-4326/ad6e9e
State	Published - Nov 1 2024

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Condensed Matter Physics

Keywords

1 MA plasma
H-mode
HL-3 experiment
advanced divertor
tokamak

Access to Document

10.1088/1741-4326/ad6e9e

Cite this

@article{95c19a90bdd74945a6bcb4be32c36b06,

title = "Recent advance progress of HL-3 experiments",

abstract = "Since the first plasma realized in 2020, a series of key systems on HL-3 (known as HL-2M before) tokamak have been equipped/upgraded, including in-vessel components (the first wall, lower divertor, and toroidal cryogenic/water-cooling/baking/glow discharge systems, etc.), auxiliary heating system of 11 MW, and 28 diagnostic systems (to measure the plasma density electron temperature, radiation, magnetic field, etc.). Magnet field systems were commissioned firstly for divertor plasma discharges. During the 2nd experimental campaign of HL-3 tokamak, several great progresses have been achieved. Firstly, the successful operation with plasma current larger than 1 MA was achieved under a divertor configuration. Secondly, the advanced divertor concept with two distinct snowflake configurations was realized. It is found that the distribution of ion saturation current and heat flux on bottom plate becomes wide due to magnetic surface expansion, demonstrating the advantage of such configuration in the heat flux mitigation. In addition, using the combination of NBI, ECRH and LHCD, the standard sawtoothing high confinement mode of megampere plasma was firstly accessed on the HL-3. The successful commissioning of HL-3 is beneficial for the initial operation of ITER.",

keywords = "1 MA plasma, H-mode, HL-3 experiment, advanced divertor, tokamak",

author = "Duan, \{X. R.\} and M. Xu and Zhong, \{W. L.\} and Ji, \{X. Q.\} and W. Chen and Shi, \{Z. B.\} and Liu, \{X. L.\} and B. Lu and B. Li and Wang, \{Y. Q.\} and Li, \{J. Q.\} and Zheng, \{G. Y.\} and Yong Liu and Yang, \{Q. W.\} and Yan, \{L. W.\} and Cai, \{L. J.\} and Q. Li and Y. Liu and Bai, \{X. Y.\} and Z. Cao and X. Chen and Chen, \{H. T.\} and Chen, \{Y. H.\} and Dong, \{G. Q.\} and Du, \{H. L.\} and Fan, \{D. M.\} and Gao, \{J. M.\} and Geng, \{S. F.\} and Hao, \{G. Z.\} and He, \{H. M.\} and M. Huang and M. Jiang and R. Ke and Liang, \{A. S.\} and Li, \{J. X.\} and Qing Li and Yongge Li and Li, \{L. C.\} and Li, \{H. J.\} and Li, \{W. B.\} and Liu, \{D. Q.\} and T. Long and Lu, \{L. F.\} and L. Nie and Shi, \{P. W.\} and Peng, \{J. F.\} and Sun, \{A. P.\} and Sun, \{T. F.\} and Tong, \{R. H.\} and Wei, \{H. L.\} and S. Wang and Xiao, \{G. L.\} and Xiao, \{X. P.\} and L. Xue and Xu, \{H. B.\} and Yang, \{Z. Y.\} and Yu, \{D. L.\} and Yu, \{L. M.\} and Zhang, \{Y. P.\} and X. Zheng and L. Zhang and Y. Zhang and F. Zhang and Zhang, \{X. L.\} and Artaud, \{J. F.\} and L. Chen and L. Delpech and A. Ekedahl and Diamond, \{P. H.\} and Ding, \{Y. H.\} and J. Garcia and Z. Gao and Gong, \{X. Y.\} and Guo, \{Z. B.\} and Hoang, \{T. G.\} and M. Isobe and Liu, \{Y. Q.\} and D. Mazon and Mckee, \{S. G.R.\} and S. Morita and Y. Peysson and Qiu, \{Z. Y.\} and Y. Ren and R. Sharples and Tynan, \{G. R.\} and Wang, \{X. G.\} and Wang, \{Z. X.\} and Xu, \{Y. H.\} and Z. Yan and G. Zhuang and F. Zonca and Zou, \{X. L.\}",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Published by IOP Publishing Ltd on behalf of the IAEA.",

year = "2024",

month = nov,

day = "1",

doi = "10.1088/1741-4326/ad6e9e",

language = "English (US)",

volume = "64",

journal = "Nuclear Fusion",

issn = "0029-5515",

publisher = "IOP Publishing Ltd.",

number = "11",

}

Duan, XR, Xu, M, Zhong, WL, Ji, XQ, Chen, W, Shi, ZB, Liu, XL, Lu, B, Li, B, Wang, YQ, Li, JQ, Zheng, GY, Liu, Y, Yang, QW, Yan, LW, Cai, LJ, Li, Q, Liu, Y, Bai, XY, Cao, Z, Chen, X, Chen, HT, Chen, YH, Dong, GQ, Du, HL, Fan, DM, Gao, JM, Geng, SF, Hao, GZ, He, HM, Huang, M, Jiang, M, Ke, R, Liang, AS, Li, JX, Li, Q, Li, Y, Li, LC, Li, HJ, Li, WB, Liu, DQ, Long, T, Lu, LF, Nie, L, Shi, PW, Peng, JF, Sun, AP, Sun, TF, Tong, RH, Wei, HL, Wang, S, Xiao, GL, Xiao, XP, Xue, L, Xu, HB, Yang, ZY, Yu, DL, Yu, LM, Zhang, YP, Zheng, X, Zhang, L, Zhang, Y, Zhang, F, Zhang, XL, Artaud, JF, Chen, L, Delpech, L, Ekedahl, A, Diamond, PH, Ding, YH, Garcia, J, Gao, Z, Gong, XY, Guo, ZB, Hoang, TG, Isobe, M, Liu, YQ, Mazon, D, Mckee, SGR, Morita, S, Peysson, Y, Qiu, ZY, Ren, Y, Sharples, R, Tynan, GR, Wang, XG, Wang, ZX, Xu, YH, Yan, Z, Zhuang, G, Zonca, F & Zou, XL 2024, 'Recent advance progress of HL-3 experiments', Nuclear Fusion, vol. 64, no. 11, 112021. https://doi.org/10.1088/1741-4326/ad6e9e

TY - JOUR

T1 - Recent advance progress of HL-3 experiments

AU - Duan, X. R.

AU - Xu, M.

AU - Zhong, W. L.

AU - Ji, X. Q.

AU - Chen, W.

AU - Shi, Z. B.

AU - Liu, X. L.

AU - Lu, B.

AU - Li, B.

AU - Wang, Y. Q.

AU - Li, J. Q.

AU - Zheng, G. Y.

AU - Liu, Yong

AU - Yang, Q. W.

AU - Yan, L. W.

AU - Cai, L. J.

AU - Li, Q.

AU - Liu, Y.

AU - Bai, X. Y.

AU - Cao, Z.

AU - Chen, X.

AU - Chen, H. T.

AU - Chen, Y. H.

AU - Dong, G. Q.

AU - Du, H. L.

AU - Fan, D. M.

AU - Gao, J. M.

AU - Geng, S. F.

AU - Hao, G. Z.

AU - He, H. M.

AU - Huang, M.

AU - Jiang, M.

AU - Ke, R.

AU - Liang, A. S.

AU - Li, J. X.

AU - Li, Qing

AU - Li, Yongge

AU - Li, L. C.

AU - Li, H. J.

AU - Li, W. B.

AU - Liu, D. Q.

AU - Long, T.

AU - Lu, L. F.

AU - Nie, L.

AU - Shi, P. W.

AU - Peng, J. F.

AU - Sun, A. P.

AU - Sun, T. F.

AU - Tong, R. H.

AU - Wei, H. L.

AU - Wang, S.

AU - Xiao, G. L.

AU - Xiao, X. P.

AU - Xue, L.

AU - Xu, H. B.

AU - Yang, Z. Y.

AU - Yu, D. L.

AU - Yu, L. M.

AU - Zhang, Y. P.

AU - Zheng, X.

AU - Zhang, L.

AU - Zhang, Y.

AU - Zhang, F.

AU - Zhang, X. L.

AU - Artaud, J. F.

AU - Chen, L.

AU - Delpech, L.

AU - Ekedahl, A.

AU - Diamond, P. H.

AU - Ding, Y. H.

AU - Garcia, J.

AU - Gao, Z.

AU - Gong, X. Y.

AU - Guo, Z. B.

AU - Hoang, T. G.

AU - Isobe, M.

AU - Liu, Y. Q.

AU - Mazon, D.

AU - Mckee, S. G.R.

AU - Morita, S.

AU - Peysson, Y.

AU - Qiu, Z. Y.

AU - Ren, Y.

AU - Sharples, R.

AU - Tynan, G. R.

AU - Wang, X. G.

AU - Wang, Z. X.

AU - Xu, Y. H.

AU - Yan, Z.

AU - Zhuang, G.

AU - Zonca, F.

AU - Zou, X. L.

PY - 2024/11/1

Y1 - 2024/11/1

N2 - Since the first plasma realized in 2020, a series of key systems on HL-3 (known as HL-2M before) tokamak have been equipped/upgraded, including in-vessel components (the first wall, lower divertor, and toroidal cryogenic/water-cooling/baking/glow discharge systems, etc.), auxiliary heating system of 11 MW, and 28 diagnostic systems (to measure the plasma density electron temperature, radiation, magnetic field, etc.). Magnet field systems were commissioned firstly for divertor plasma discharges. During the 2nd experimental campaign of HL-3 tokamak, several great progresses have been achieved. Firstly, the successful operation with plasma current larger than 1 MA was achieved under a divertor configuration. Secondly, the advanced divertor concept with two distinct snowflake configurations was realized. It is found that the distribution of ion saturation current and heat flux on bottom plate becomes wide due to magnetic surface expansion, demonstrating the advantage of such configuration in the heat flux mitigation. In addition, using the combination of NBI, ECRH and LHCD, the standard sawtoothing high confinement mode of megampere plasma was firstly accessed on the HL-3. The successful commissioning of HL-3 is beneficial for the initial operation of ITER.

AB - Since the first plasma realized in 2020, a series of key systems on HL-3 (known as HL-2M before) tokamak have been equipped/upgraded, including in-vessel components (the first wall, lower divertor, and toroidal cryogenic/water-cooling/baking/glow discharge systems, etc.), auxiliary heating system of 11 MW, and 28 diagnostic systems (to measure the plasma density electron temperature, radiation, magnetic field, etc.). Magnet field systems were commissioned firstly for divertor plasma discharges. During the 2nd experimental campaign of HL-3 tokamak, several great progresses have been achieved. Firstly, the successful operation with plasma current larger than 1 MA was achieved under a divertor configuration. Secondly, the advanced divertor concept with two distinct snowflake configurations was realized. It is found that the distribution of ion saturation current and heat flux on bottom plate becomes wide due to magnetic surface expansion, demonstrating the advantage of such configuration in the heat flux mitigation. In addition, using the combination of NBI, ECRH and LHCD, the standard sawtoothing high confinement mode of megampere plasma was firstly accessed on the HL-3. The successful commissioning of HL-3 is beneficial for the initial operation of ITER.

KW - 1 MA plasma

KW - H-mode

KW - HL-3 experiment

KW - advanced divertor

KW - tokamak

UR - https://www.scopus.com/pages/publications/85203389137

UR - https://www.scopus.com/pages/publications/85203389137#tab=citedBy

U2 - 10.1088/1741-4326/ad6e9e

DO - 10.1088/1741-4326/ad6e9e

M3 - Article

AN - SCOPUS:85203389137

SN - 0029-5515

VL - 64

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 11

M1 - 112021

ER -

Recent advance progress of HL-3 experiments

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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