Realization of thousand-second improved confinement plasma with Super I-mode in Tokamak EAST.

Yuntao Song Xiaolan Zou Xianzu Gong Alain Becoulet Richard Buttery Paul Bonoli Tuong Hoang Rajesh Maingi Jinping Qian Xiaoming Zhong Adi Liu Erzhong Li Rui Ding Juan Huang Qing Zang Haiqing Liu Liang Wang Ling Zhang Guoqiang Li Youwen Sun Andrea Garofalo Tom Osborne Tony Leonard Seung Gyou Baek Greg Wallace Liqing Xu Bin Zhang Shouxin Wang Yuqi Chu Tao Zhang Yanmin Duan Hui Lian Xuexi Zhang Yifei Jin Long Zeng Bo Lyu Binjia Xiao Yao Huang Yong Wang Biao Shen Nong Xiang Yu Wu Jiefeng Wu Xiaojie Wang Bojiang Ding Miaohui Li Xinjun Zhang Chengming Qin Weibin Xi Jian Zhang Liansheng Huang Damao Yao Yanlan Hu Guizhong Zuo Qiping Yuan Zhiwei Zhou Mao Wang Handong Xu Yahong Xie Zhengchu Wang Junling Chen Guosheng Xu Jiansheng Hu Kun Lu Fukun Liu Xinchao Wu Baonian Wan Jiangang Linull null

Published in: Science advances (2023)

Mastering nuclear fusion, which is an abundant, safe, and environmentally competitive energy, is a great challenge for humanity. Tokamak represents one of the most promising paths toward controlled fusion. Obtaining a high-performance, steady-state, and long-pulse plasma regime remains a critical issue. Recently, a big breakthrough in steady-state operation was made on the Experimental Advanced Superconducting Tokamak (EAST). A steady-state plasma with a world-record pulse length of 1056 s was obtained, where the density and the divertor peak heat flux were well controlled, with no core impurity accumulation, and a new high-confinement and self-organizing regime (Super I-mode = I-mode + e-ITB) was discovered and demonstrated. These achievements contribute to the integration of fusion plasma technology and physics, which is essential to operate next-step devices.

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