The seeding of neoclassical tearing modes by resonant magnetic perturbations in the EAST tokamak

• Published in: Nuclear fusion Vol. 64; no. 12; pp. 126066 - 126082
• Main Authors: Shi, Tonghui, Wei, L., Sun, Y.W., Wang, H.H., Ma, Q., Li, E., Zhang, Y., Qian, J.P., Zeng, L., Shen, B., Wang, Y.M., Zhang, T., Zhao, H.L., Liu, H.Q., Luo, Z.P., Li, Y.Y., Xu, L.Q., Zhang, B., Li, M.H., Wang, Z.X., Ling, B.L., Gong, X.Z., Wan, B.N.
• Format: Journal Article
• Language: English
• Published: IOP Publishing 01.12.2024
• Subjects: mode penetration; NTM triggering; RMP; seed island
• ISSN: 0029-5515; 1741-4326
• DOI: 10.1088/1741-4326/ad89dc

Abstract This work presents a robust methodology for effectively distinguishing between the seed island and the onset of the neoclassical tearing mode (NTM) in the EAST tokamak. Unlike previously employed methods, the width of the seed island is carefully regulated by gradually ramping up the currents in the resonant magnetic perturbation (RMP) coils. Remarkably, the seed island phase can be sustained for several hundred milliseconds, providing ample time to examine the nonlinear dynamics of NTM threshold physics. This study investigates the plasma response in terms of various factors, including the plasma rotation, the electron density, and the electron temperature, from the initial formation of the seed island to the saturation of the NTM island. Through extensive statistical analysis of NTM triggering events, it is revealed that both the critical width of the seed island and the critical RMP currents are positively correlated with β p . Moreover, the relationship of the transition time associated with mode penetration to β p differs from the dependence of the transition time for NTM triggering on β p . The growth rates associated with these two nonlinear phenomena show similar characteristics. Finally, reduced magnetohydrodynamic (MHD) modeling replicates the two nonlinear bifurcation states observed in the experiment. It is noteworthy that the RMP-induced NTM islands are locked to the static magnetic perturbation. This scenario differs from the natural excitation of NTMs, which occurs due to transient MHD phenomena, such as sawtooth crashes, where the triggering source is a rotating magnetic perturbation. This leads to the formation of rapidly rotating islands at a natural frequency. Furthermore, the stability of these islands is expected to be related to the polarization current effect. Nevertheless, this experiment sets a new course for the comprehensive investigation and understanding of NTM threshold physics, providing valuable insights for future tokamak design and operational strategies.