\begin{document}$ {H}_{98} $\end{document}is 1.25–1.35, and \begin{document}$ {f}_{{\rm{n}}{\rm{G}}} $\end{document}~0.9. Additionally, to maintain the total non-inductive current, the total heating/current drive power needs to be highly sensitive to plasma confinement and density, which is the most effective way to increase the bootstrap current fraction and reduce the peak heat loads on the divertor. Improving plasma confinement is the most effective way to achieve high bootstrap current fraction and reduce the peak heat load on the divertor. In this work, we also analyze the effect of heating power ratio on the bootstrap current, showing that adjusting the power ratio can change the bootstrap current fraction, and we further analyze the long-pulse operating region of EAST with a plasma current of 500 kA. In the range of 9.5 MW total heating/current driving power, \begin{document}$ {H}_{98} $\end{document} is 1.0–1.4, and normalized electron density \begin{document}$ {f}_{{\rm{n}}{\rm{G}}} $\end{document} is 0.8–1.0, high-performance long-pulse or fully non-inductive steady-state operation can be achieved, supporting the research on the physics of ITER and CFETR steady-state operation modes. In general, improving the plasma confinement performance can achieve fully non-inductive operation at lower heating/driving power while maintaining the same plasma parameters, and expand the plasma operating regime, which is the most effective way to achieve high-parameter steady-state operation of the plasma."> - 必威体育下载

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    Yu Ming-Sheng, Qian Jin-Ping, Ding Si-Ye, Ren Qi-Long, Ye Yang, Wan Bao-Nian
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    • Abstract views:2468
    • PDF Downloads:48
    • Cited By:0
    Publishing process
    • Received Date:10 March 2023
    • Accepted Date:04 April 2023
    • Available Online:11 April 2023
    • Published Online:05 June 2023

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