| Autor: |
Young Ho Lee, Woong Chae Kim, SangKyeun Kim, Gyungjin Choi, Boseong Kim, Won-Ha Ko, Jaemin Seo, Sang Hee Hahn, Jinwoo Gwak, Si-Woo Yoon, Jung Hee Kim, K.D. Lee, Minjun Choi, SeongMoo Yang, Minsoo Cha, Jekil Lee, T.S. Hahm, Jong-Kyu Park, Kwan Chul Lee, Yong-Su Na, Hyunsun Han, Chanyoung Lee, Juhyeok Jang, Jaehyun Lee, Jungpyo Lee, Jinil Jung, Young-Seok Park, Jisung Kang, Sangjin Park, Jinseok Ko, Choongki Sung |
| Rok vydání: |
2021 |
| Předmět: |
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| DOI: |
10.21203/rs.3.rs-935325/v1 |
| Popis: |
We report a discovery of a fusion plasma regime suitable for commercial fusion reactor where the ion temperature was sustained above 100 million degree about 20 s for the first time. Nuclear fusion as a promising technology for replacing carbon-dependent energy sources has currently many issues to be resolved to enable its large-scale use as a sustainable energy source. State-of-the-art fusion reactors cannot yet achieve the high levels of fusion performance, high temperature, and absence of instabilities required for steady-state operation for a long period of time on the order of hundreds of seconds. This is a pressing challenge within the field, as the development of methods that would enable such capabilities is essential for the successful construction of commercial fusion reactor. Here, a new plasma confinement regime called fast ion roled enhancement (FIRE) mode is presented. This mode is realized at Korea Superconducting Tokamak Advanced Research (KSTAR) and subsequently characterized to show that it meets most of the requirements for fusion reactor commercialization. Through a comparison to other well-known plasma confinement regimes, the favourable properties of FIRE mode are further elucidated and concluded that the novelty lies in the high fraction of fast ions, which acts to stabilize turbulence and achieve steady-state operation for up to 20 s by self-organization. We propose this mode as a promising path towards commercial fusion reactors. |
| Databáze: |
OpenAIRE |
| Externí odkaz: |
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