On the role of ion temperature gradient turbulence in driving ion thermal transport in neutral beam injection-heated L-mode plasmas in a superconducting tokamak

On the role of ion temperature gradient turbulence in driving ion thermal transport in neutral beam injection-heated L-mode plasmas in a superconducting tokamak

In this paper, we report a detailed experimental study of the role of ion-temperature-gradient driven turbulence in driving ion thermal transport in neutral beam injection (NBI)-heated L-mode plasmas in Experimental Advanced Superconducting Tokamak (EAST) (Wan et al 2000 Nucl. Fusion 40 1057) couple...

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Main Authors: P.J. Sun, Y. Ren, W.X. Wang, X.F. Han, H.Q. Liu, Y.D. Li, G.S. Li, Y.F. Wang, B.L. Hao, Y.L. Zhu, X.Z. Liu, X.L. Li, Z.P. Luo, S.X. Wang, Y.Q. Chu, Y.F. Jin, S.Y. Fu, H.L. Zhao, X.D. Zhang, the EAST Team
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:Nuclear Fusion
Subjects:
ITG turbulence
thermal transport
gyrokinetic simulation
EAST tokamak
Online Access:https://doi.org/10.1088/1741-4326/ade8fc
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Summary:In this paper, we report a detailed experimental study of the role of ion-temperature-gradient driven turbulence in driving ion thermal transport in neutral beam injection (NBI)-heated L-mode plasmas in Experimental Advanced Superconducting Tokamak (EAST) (Wan et al 2000 Nucl. Fusion 40 1057) coupled with linear and nonlinear gyrokinetic simulations. Significant ion-scale turbulence $k_{\perp} \lt 5$ cm ^−1 ( $k_{\perp}\rho_s \lt 1.5$ , where $k_{\perp}$ is the perpendicular wavenumber and ρ _s is the ion gyroradius calculated using local electron temperature T _e ), measured with a microwave reflectometer, is observed in the plasma core at for $r/a\approx0.265$ and 0.5 (where r is half the diameter of the closed flux surface at a given radial position, and a is half the diameter of the last closed flux surface). Local linear stability analysis with experimental equilibrium quantities at these two radial locations using the GS2 gyrokinetic code shows that the most unstable ion-scale micro-instability is the ion temperature gradient (ITG) mode. Since the computed maximum ion-scale linear growth rates are larger than the local Waltz-Miller E  ×  B shearing rate (Waltz and Miller 1999 Phys. Plasmas 6 4265), the E  ×  B shear is unable to suppress ion-scale turbulence, consistent with the experimental observation of ion-scale turbulence. Experimental ion and electron thermal transports, calculated with power balance analysis, are both anomalous with ion thermal transport being the dominant channel. Nonlinear gyrokinetic simulations using the electrostatic global particle-in-cell gyrokinetic tokamak simulation (GTS) code (Weixing Wang et al 2010 Phys. Plasmas 17 072511) show good quantitative agreement between predicted ion thermal transport and that from the power balance analysis. These results demonstrate for the first time the important role of ITG turbulence in driving thermal transport in NBI-heated L-mode plasmas in EAST, showing the effectiveness of GTS code in simulating electrostatic turbulence in EAST and the need of suppressing ITG turbulence to improve energy confinement in EAST.
ISSN:0029-5515

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