Enhancement of edge turbulence concomitant with ELM suppression during boron powder injection in EAST
Zhen Sun, R. Maingi, A. Diallo, Wei Xu, Y. Z. Qian, K. Tritz, Y. Ye, C.L. Li, Zong Xu, Yifeng Wang, Kaixuan Ye, A. Bortolon, A. Nagy, Ling Zhang, Yanmin Duan, Zhiyuan Lu, Huiqian Wang, Tonghui Shi, Hailin Zhao, W. Gao, J.C. Xu, R. Chen, M. Huang, Guizhong Zuo, Guosheng Xu, Xianzu Gong, Jiansheng Hu, EAST Team
Abstract
A reproducible, quasi-stationary edge localized mode (ELM)-suppressed scenario was obtained over a wide range of plasma parameters by continuous injection of boron (B) powder into an upper-single null discharge in the experimental advanced superconducting tokamak [Sun et al., Nucl. Fusion 61, 014002 (2021)]. This powder-induced ELM-absent regime is associated with an edge harmonic mode (EHM) that provides continuous particle exhaust to maintain constant density without confinement degradation and impurity accumulation, the latter of which is often observed in ELM-free regimes. A flow rate threshold of B powder injection, leading to a threshold intensity of the EHM, is necessary for full ELM suppression. The fundamental harmonic of the EHM exhibits a toroidal mode number n = 1. The mode is observable in the entire poloidal cross section with a peak near the upper X-point in an upper-single null configuration. The EHM spans radially across the pedestal and scrape-off layer, peaking inside the separatrix. The EHM appears to be insensitive to q95, heating power, plasma toroidal rotation, and pedestal collisionality.