Detailed characterization of runaway electron driven whistler waves in low-density DIII-D discharges

H. Choudhury; A. Battey; C. Paz-Soldan; W. Heidbrink; G. DeGrandchamp; C. Marini; A. Lvovskiy; Y. Ghai; D. Spong

doi:10.1063/5.0277589

Detailed characterization of runaway electron driven whistler waves in low-density DIII-D discharges

H. Choudhury
, A. Battey
, C. Paz-Soldan
, W. Heidbrink
, G. DeGrandchamp
, C. Marini
, A. Lvovskiy
, Y. Ghai
, D. Spong

Fusion Theory and Modeling

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

RE-driven whistler waves during quiescent DIII-D shots have been investigated further. The waves are confirmed to be mostly perpendicularly propagating and are observed for the first time with frequencies up to 700 MHz. Phase-spectral analysis has been used to infer their toroidal mode numbers, n, which are expected to scale with the wavenumber, k, of the mode. Though we derive a theoretical scaling of k ≈ 4 n , the measured mode numbers are found to exhibit a very weak dependence on k. In addition, increases in synchrotron emission have been found to consistently lag whistler wave bursts by roughly 3-5 ms, suggesting the waves are causing pitch-angle scattering, since the emitted synchrotron radiation is a strong function of the REs' perpendicular energy. The stronger the wave bursts, the greater the subsequent increase in synchrotron emission. A predator-prey model is used to describe these nonlinear wave-particle interactions, from which the wave damping rates and the loss parameter can be inferred. The damping rates are found to be of the order of ( 1.6 ± 0.8 ) × 10 4 /s, and the unitless loss parameter is found to be approximately 2, suggesting that the loss mechanism is diffusive. These observations will serve to validate models of RE-driven waves in tokamak plasmas.

Original language	English
Article number	092508
Journal	Physics of Plasmas
Volume	32
Issue number	9
DOIs	https://doi.org/10.1063/5.0277589
State	Published - Sep 1 2025

Funding

This material is based upon work supported by the U.S. Department of Energy, Office of Science, Office of Fusion Energy Sciences, using the DIII-D National Fusion Facility, a DOE Office of Science user facility (Award Nos. DE-FC02-04ER54698, DE-SC0022270, DE-SC0021622, DE-SC0021624, DE-SC0020337, and DE-FG02-07ER54917).

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title = "Detailed characterization of runaway electron driven whistler waves in low-density DIII-D discharges",

abstract = "RE-driven whistler waves during quiescent DIII-D shots have been investigated further. The waves are confirmed to be mostly perpendicularly propagating and are observed for the first time with frequencies up to 700 MHz. Phase-spectral analysis has been used to infer their toroidal mode numbers, n, which are expected to scale with the wavenumber, k, of the mode. Though we derive a theoretical scaling of k ≈ 4 n , the measured mode numbers are found to exhibit a very weak dependence on k. In addition, increases in synchrotron emission have been found to consistently lag whistler wave bursts by roughly 3-5 ms, suggesting the waves are causing pitch-angle scattering, since the emitted synchrotron radiation is a strong function of the REs' perpendicular energy. The stronger the wave bursts, the greater the subsequent increase in synchrotron emission. A predator-prey model is used to describe these nonlinear wave-particle interactions, from which the wave damping rates and the loss parameter can be inferred. The damping rates are found to be of the order of ( 1.6 ± 0.8 ) × 10 4 /s, and the unitless loss parameter is found to be approximately 2, suggesting that the loss mechanism is diffusive. These observations will serve to validate models of RE-driven waves in tokamak plasmas.",

author = "H. Choudhury and A. Battey and C. Paz-Soldan and W. Heidbrink and G. DeGrandchamp and C. Marini and A. Lvovskiy and Y. Ghai and D. Spong",

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AU - Choudhury, H.

AU - Battey, A.

AU - Paz-Soldan, C.

AU - Heidbrink, W.

AU - DeGrandchamp, G.

AU - Marini, C.

AU - Lvovskiy, A.

AU - Ghai, Y.

AU - Spong, D.

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N2 - RE-driven whistler waves during quiescent DIII-D shots have been investigated further. The waves are confirmed to be mostly perpendicularly propagating and are observed for the first time with frequencies up to 700 MHz. Phase-spectral analysis has been used to infer their toroidal mode numbers, n, which are expected to scale with the wavenumber, k, of the mode. Though we derive a theoretical scaling of k ≈ 4 n , the measured mode numbers are found to exhibit a very weak dependence on k. In addition, increases in synchrotron emission have been found to consistently lag whistler wave bursts by roughly 3-5 ms, suggesting the waves are causing pitch-angle scattering, since the emitted synchrotron radiation is a strong function of the REs' perpendicular energy. The stronger the wave bursts, the greater the subsequent increase in synchrotron emission. A predator-prey model is used to describe these nonlinear wave-particle interactions, from which the wave damping rates and the loss parameter can be inferred. The damping rates are found to be of the order of ( 1.6 ± 0.8 ) × 10 4 /s, and the unitless loss parameter is found to be approximately 2, suggesting that the loss mechanism is diffusive. These observations will serve to validate models of RE-driven waves in tokamak plasmas.

AB - RE-driven whistler waves during quiescent DIII-D shots have been investigated further. The waves are confirmed to be mostly perpendicularly propagating and are observed for the first time with frequencies up to 700 MHz. Phase-spectral analysis has been used to infer their toroidal mode numbers, n, which are expected to scale with the wavenumber, k, of the mode. Though we derive a theoretical scaling of k ≈ 4 n , the measured mode numbers are found to exhibit a very weak dependence on k. In addition, increases in synchrotron emission have been found to consistently lag whistler wave bursts by roughly 3-5 ms, suggesting the waves are causing pitch-angle scattering, since the emitted synchrotron radiation is a strong function of the REs' perpendicular energy. The stronger the wave bursts, the greater the subsequent increase in synchrotron emission. A predator-prey model is used to describe these nonlinear wave-particle interactions, from which the wave damping rates and the loss parameter can be inferred. The damping rates are found to be of the order of ( 1.6 ± 0.8 ) × 10 4 /s, and the unitless loss parameter is found to be approximately 2, suggesting that the loss mechanism is diffusive. These observations will serve to validate models of RE-driven waves in tokamak plasmas.

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Detailed characterization of runaway electron driven whistler waves in low-density DIII-D discharges

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