Hollow current and reversed magnetic shear configurations in pellet injection discharges on Huanliuqi 2A tokamak

Yong, Shen; Dong, J. Q.; He, Hao; Ding, X.T.; Zhongbing, Shi; Ji, X.Q.; Jia, Li; Ming-Kun, Han; Wu, Na; Jiang, M.; Wang, Shuo; Li, Jiquan; Xu, M.; Duan, X.R.

doi:10.7498/aps.70.20210641

Cited by 1 publication

(1 citation statement)

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“…径𝑎与磁场𝐵单位分别是 m 和 Tesla。可以通过优化等离子体剖面、使等离子体发生形变 [1] ，以及优化稳定性、输运和优化偏滤器运行等措施 [17] ，来提高运行𝛽，实现稳态放电 [2] 。有些放电如 HL-2A 装置弹丸注入中空电流型放电的𝛽 是低的，但存在中心负磁剪切位形和内部输运垒 [18,19] 。 Garofaro 等 [20] 讨论了通过内部输运垒和中心负磁磁切来来实现可持续的高𝛽放电。在上述问题中，人们关注的重点是改进 MHD 稳定性 [21][22][23] 。大量的研究结果还表明，如果在离等离子体中心 1.5…”

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Ideal conductive wall and magnetohydrodynamic instability in Tokamak

Shen¹,

Dong²,

He³

et al. 2023

Acta Phys. Sin.

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In order to explore the conductive wall effect of plasma magnetohydrodynamic (MHD) instability and the wall designing idea, the various forms of ideal conductive walls based on divertor equilibrium configurations in the HL-2A tokamak and their role in the suppression of kink modes were studied. The MHD instabilities and the ideal MHD operational β limits under free boundary or ideal wall conditions were compared. In the stability calculation,n=1 kink mode was considered, which had a decisive influence on the MHD instability of tokamak plasmas. The research focuses on verifying the effectiveness of various shapes of conductive walls in suppressing internal and external kink modes, and observing the operational β limit changes, and discussing and analyzing related physics. It is found that an ideal conducting wall placed at a suitable distance from the plasma could effectively suppress the external kink modes. Under the condition that the average distance between the wall and the plasma surface is the same and small enough, the circular cross-section wall is not necessarily the best choice. Setting an optimized polygonal conductive wall can more effectively suppress the MHD instability. It makes the ideal MHD operational β limit of the device, βN, increase to 2.73, which is about 6.5% higher than that for the device with a wall assumed to be set at infinity (~2.56). This implies that it is necessary to optimize and make a polygonal conductive wall as close as possible to the average distance from the plasma surface according to the poloidal-section shape of the elongated and shaped plasma, so as to achieve the suppression of external kink mode and increase the operational β limits. The physical mechanism of the stabilizing effect of the ideal wall on external kink modes was analyzed. With the development of the kink mode, when the plasma column is twisted close to the wall, the plasma column will squeeze the magnetic field in the vacuum area, making the magnetic field line compressed and bent. At this time, the magnetic pressure and the component force of the magnetic tension in the opposite direction of the radial direction push the plasma back, thus stabilizing the kink mode. Finally, a conclusion was given.

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