A sustained high-temperature fusion plasma regime facilitated by fast ions

H. Han; S. J. Park; C. Sung; J. Kang; Y. H. Lee; J. Chung; T. S. Hahm; B. Kim; J. K. Park; J. G. Bak; M. S. Cha; G. J. Choi; M. J. Choi; J. Gwak; S. H. Hahn; J. Jang; K. C. Lee; J. H. Kim; S. K. Kim; W. C. Kim; J. Ko; W. H. Ko; C. Y. Lee; J. H. Lee; J. H. Lee; J. K. Lee; J. P. Lee; K. D. Lee; Y. S. Park; J. Seo; S. M. Yang; S. W. Yoon; Y. S. Na

doi:10.1038/s41586-022-05008-1

A sustained high-temperature fusion plasma regime facilitated by fast ions

H. Han
, S. J. Park
, C. Sung
, J. Kang
, Y. H. Lee
, J. Chung
, T. S. Hahm
, B. Kim
, J. K. Park
, J. G. Bak
, M. S. Cha
, G. J. Choi
, M. J. Choi
, J. Gwak
, S. H. Hahn
, J. Jang
, K. C. Lee
, J. H. Kim
, S. K. Kim
, W. C. Kim

J. Ko, W. H. Ko, C. Y. Lee, J. H. Lee, J. H. Lee, J. K. Lee, J. P. Lee, K. D. Lee, Y. S. Park, J. Seo, S. M. Yang, S. W. Yoon, Y. S. Na

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

93 Scopus citations

Abstract

Nuclear fusion is one of the most attractive alternatives to carbon-dependent energy sources¹. Harnessing energy from nuclear fusion in a large reactor scale, however, still presents many scientific challenges despite the many years of research and steady advances in magnetic confinement approaches. State-of-the-art magnetic fusion devices cannot yet achieve a sustainable fusion performance, which requires a high temperature above 100 million kelvin and sufficient control of instabilities to ensure steady-state operation on the order of tens of seconds^2,3. Here we report experiments at the Korea Superconducting Tokamak Advanced Research⁴ device producing a plasma fusion regime that satisfies most of the above requirements: thanks to abundant fast ions stabilizing the core plasma turbulence, we generate plasmas at a temperature of 100 million kelvin lasting up to 20 seconds without plasma edge instabilities or impurity accumulation. A low plasma density combined with a moderate input power for operation is key to establishing this regime by preserving a high fraction of fast ions. This regime is rarely subject to disruption and can be sustained reliably even without a sophisticated control, and thus represents a promising path towards commercial fusion reactors.

Original language	English (US)
Pages (from-to)	269-275
Number of pages	7
Journal	Nature
Volume	609
Issue number	7926
DOIs	https://doi.org/10.1038/s41586-022-05008-1
State	Published - Sep 8 2022

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Han, H., Park, S. J., Sung, C., Kang, J., Lee, Y. H., Chung, J., Hahm, T. S., Kim, B., Park, J. K., Bak, J. G., Cha, M. S., Choi, G. J., Choi, M. J., Gwak, J., Hahn, S. H., Jang, J., Lee, K. C., Kim, J. H., Kim, S. K., ... Na, Y. S. (2022). A sustained high-temperature fusion plasma regime facilitated by fast ions. Nature, 609(7926), 269-275. https://doi.org/10.1038/s41586-022-05008-1

@article{1480a4afbd0344f78200379131bf3e34,

title = "A sustained high-temperature fusion plasma regime facilitated by fast ions",

abstract = "Nuclear fusion is one of the most attractive alternatives to carbon-dependent energy sources1. Harnessing energy from nuclear fusion in a large reactor scale, however, still presents many scientific challenges despite the many years of research and steady advances in magnetic confinement approaches. State-of-the-art magnetic fusion devices cannot yet achieve a sustainable fusion performance, which requires a high temperature above 100 million kelvin and sufficient control of instabilities to ensure steady-state operation on the order of tens of seconds2,3. Here we report experiments at the Korea Superconducting Tokamak Advanced Research4 device producing a plasma fusion regime that satisfies most of the above requirements: thanks to abundant fast ions stabilizing the core plasma turbulence, we generate plasmas at a temperature of 100 million kelvin lasting up to 20 seconds without plasma edge instabilities or impurity accumulation. A low plasma density combined with a moderate input power for operation is key to establishing this regime by preserving a high fraction of fast ions. This regime is rarely subject to disruption and can be sustained reliably even without a sophisticated control, and thus represents a promising path towards commercial fusion reactors.",

author = "H. Han and Park, \{S. J.\} and C. Sung and J. Kang and Lee, \{Y. H.\} and J. Chung and Hahm, \{T. S.\} and B. Kim and Park, \{J. K.\} and Bak, \{J. G.\} and Cha, \{M. S.\} and Choi, \{G. J.\} and Choi, \{M. J.\} and J. Gwak and Hahn, \{S. H.\} and J. Jang and Lee, \{K. C.\} and Kim, \{J. H.\} and Kim, \{S. K.\} and Kim, \{W. C.\} and J. Ko and Ko, \{W. H.\} and Lee, \{C. Y.\} and Lee, \{J. H.\} and Lee, \{J. H.\} and Lee, \{J. K.\} and Lee, \{J. P.\} and Lee, \{K. D.\} and Park, \{Y. S.\} and J. Seo and Yang, \{S. M.\} and Yoon, \{S. W.\} and Na, \{Y. S.\}",

note = "Publisher Copyright: {\textcopyright} 2022, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2022",

month = sep,

day = "8",

doi = "10.1038/s41586-022-05008-1",

language = "English (US)",

volume = "609",

pages = "269--275",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

number = "7926",

}

Han, H, Park, SJ, Sung, C, Kang, J, Lee, YH, Chung, J, Hahm, TS, Kim, B, Park, JK, Bak, JG, Cha, MS, Choi, GJ, Choi, MJ, Gwak, J, Hahn, SH, Jang, J, Lee, KC, Kim, JH, Kim, SK, Kim, WC, Ko, J, Ko, WH, Lee, CY, Lee, JH, Lee, JH, Lee, JK, Lee, JP, Lee, KD, Park, YS, Seo, J, Yang, SM, Yoon, SW & Na, YS 2022, 'A sustained high-temperature fusion plasma regime facilitated by fast ions', Nature, vol. 609, no. 7926, pp. 269-275. https://doi.org/10.1038/s41586-022-05008-1

TY - JOUR

T1 - A sustained high-temperature fusion plasma regime facilitated by fast ions

AU - Han, H.

AU - Park, S. J.

AU - Sung, C.

AU - Kang, J.

AU - Lee, Y. H.

AU - Chung, J.

AU - Hahm, T. S.

AU - Kim, B.

AU - Park, J. K.

AU - Bak, J. G.

AU - Cha, M. S.

AU - Choi, G. J.

AU - Choi, M. J.

AU - Gwak, J.

AU - Hahn, S. H.

AU - Jang, J.

AU - Lee, K. C.

AU - Kim, J. H.

AU - Kim, S. K.

AU - Kim, W. C.

AU - Ko, J.

AU - Ko, W. H.

AU - Lee, C. Y.

AU - Lee, J. H.

AU - Lee, J. K.

AU - Lee, J. P.

AU - Lee, K. D.

AU - Park, Y. S.

AU - Seo, J.

AU - Yang, S. M.

AU - Yoon, S. W.

AU - Na, Y. S.

PY - 2022/9/8

Y1 - 2022/9/8

N2 - Nuclear fusion is one of the most attractive alternatives to carbon-dependent energy sources1. Harnessing energy from nuclear fusion in a large reactor scale, however, still presents many scientific challenges despite the many years of research and steady advances in magnetic confinement approaches. State-of-the-art magnetic fusion devices cannot yet achieve a sustainable fusion performance, which requires a high temperature above 100 million kelvin and sufficient control of instabilities to ensure steady-state operation on the order of tens of seconds2,3. Here we report experiments at the Korea Superconducting Tokamak Advanced Research4 device producing a plasma fusion regime that satisfies most of the above requirements: thanks to abundant fast ions stabilizing the core plasma turbulence, we generate plasmas at a temperature of 100 million kelvin lasting up to 20 seconds without plasma edge instabilities or impurity accumulation. A low plasma density combined with a moderate input power for operation is key to establishing this regime by preserving a high fraction of fast ions. This regime is rarely subject to disruption and can be sustained reliably even without a sophisticated control, and thus represents a promising path towards commercial fusion reactors.

AB - Nuclear fusion is one of the most attractive alternatives to carbon-dependent energy sources1. Harnessing energy from nuclear fusion in a large reactor scale, however, still presents many scientific challenges despite the many years of research and steady advances in magnetic confinement approaches. State-of-the-art magnetic fusion devices cannot yet achieve a sustainable fusion performance, which requires a high temperature above 100 million kelvin and sufficient control of instabilities to ensure steady-state operation on the order of tens of seconds2,3. Here we report experiments at the Korea Superconducting Tokamak Advanced Research4 device producing a plasma fusion regime that satisfies most of the above requirements: thanks to abundant fast ions stabilizing the core plasma turbulence, we generate plasmas at a temperature of 100 million kelvin lasting up to 20 seconds without plasma edge instabilities or impurity accumulation. A low plasma density combined with a moderate input power for operation is key to establishing this regime by preserving a high fraction of fast ions. This regime is rarely subject to disruption and can be sustained reliably even without a sophisticated control, and thus represents a promising path towards commercial fusion reactors.

UR - https://www.scopus.com/pages/publications/85137510035

UR - https://www.scopus.com/pages/publications/85137510035#tab=citedBy

U2 - 10.1038/s41586-022-05008-1

DO - 10.1038/s41586-022-05008-1

M3 - Article

C2 - 36071190

AN - SCOPUS:85137510035

SN - 0028-0836

VL - 609

SP - 269

EP - 275

JO - Nature

JF - Nature

IS - 7926

ER -

A sustained high-temperature fusion plasma regime facilitated by fast ions

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