Resolving ECRH deposition broadening due to edge turbulence in DIII-D by heat deposition measurement

TL;DR

This paper investigates how edge turbulence broadens ECRH deposition profiles in DIII-D, combining experimental measurements and modeling to quantify the broadening effect and its correlation with turbulence levels.

Contribution

It introduces a novel heat flux measurement method to quantify ECRH deposition broadening caused by edge turbulence in tokamaks.

Findings

Deposition broadening scales linearly with edge density fluctuations.

Experimental results agree with full-wave beam broadening simulations.

The method improves the accuracy of heat deposition profile assessments.

Abstract

Interaction between microwave power, used for local heating and mode control, and density fluctuations can produce a broadening of the injected beam, as confirmed in experiment and simulation. Increased power deposition width could impact suppression of tearing mode structures on ITER. This work discusses the experimental portion of an effort to understand scattering of injected microwaves by turbulence on the DIII-D tokamak. The corresponding theoretical modeling work can be found in M.B. Thomas et. al.: Submitted to Nuclear Fusion (2017)[Author Note - this paper to be published in same journal]. In a set of perturbative heat transport experiments, tokamak edge millimeter-scale fluctuation levels and microwave heat deposition are measured simultaneously. Beam broadening is separated from heat transport through fitting of modulated fluxes. Electron temperature measurements from a 500 kHz, 48-channel ECE radiometer are Fourier analyzed and used to calculate a deposition-dependent flux. Consistency of this flux with a transport model is evaluated. A diffusive and convective transport solution is linearized and compared with energy conservation-derived fluxes. Comparison between these two forms of heat flux is used to evaluate the quality of ECRF deposition profiles, and fitting finds a significant broadening of 1D equilibrium ray tracing calculations from the benchmarked TORAY-GA ray tracing code is needed. The physical basis, cross-validation, and application of the heat flux method is presented. The method is applied to a range of DIII-D discharges and finds a broadening factor of the deposition profile width which scales linearly with edge density fluctuation level. These experimental results are found to be consistent with the full-wave beam broadening measured by the 3D full wave simulations in the same discharges.