Effect of Partially Screened Nuclei on Fast-Electron Dynamics

Hesslow, Linnea; Embréus, Ola; Stahl, Adam; DuBois, Timothy C.; Papp, G.; Newton, Sarah; Fülöp, Tünde

doi:10.1103/physrevlett.118.255001

Cited by 58 publications

(114 citation statements)

References 33 publications

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“…Histograms of measured θ pol and f pol are shown in figures 2a and 2b, respectively. The distributions of θ pol are well-localized for most channels, and an interesting The discharge numbers are 2, 3,6,7,14,16,17,19,20,[23][24][25][26]30, and 34 for experiment #1140403; 15 and 18-22 for experiment #1151002; and 20, 21, and 23-27 for experiment #1160824. spatial trend is observed: At the innermost radius (channel 1, r tan /a = −0.4), θ pol ≈ 0 • indicates horizontally-polarized synchrotron light. ¶ For |r tan /a| ≤ 0.23, i.e.…”

Section: Methodsmentioning

confidence: 95%

Experimental and synthetic measurements of polarized synchrotron emission from runaway electrons in Alcator C-Mod

et al. 2019

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This paper presents the first experimental analysis of polarized synchrotron emission from relativistic runaway electrons (REs) in a tokamak plasma. Importantly, we show that the polarization information of synchrotron radiation can be used to diagnose spatially-localized RE pitch angle distributions. Synchrotron-producing REs were generated during low density, Ohmic, diverted plasma discharges in the Alcator C-Mod tokamak. The ten-channel Motional Stark Effect diagnostic was used to measure spatial profiles of the polarization angle θ pol and the fraction f pol of detected light that was linearly-polarized. Spatial transitions in θ pol of 90 • -from horizontal to vertical polarization and vice versaare observed in experimental data and are well-explained by the gyro-motion of REs and high directionality of synchrotron radiation. Polarized synchrotron emission is modeled with the synthetic diagnostic Soft; its output Green's (or detector response) functions reveal a critical RE pitch angle at which θ pol flips by 90 • and f pol is minimal. Using Soft, we determine the dominant RE pitch angle which reproduces measured θ pol and f pol values. The spatiotemporal evolutions of θ pol and f pol are explored in detail for one C-Mod discharge. For channels viewing REs near the magnetic axis and flux surfaces q = 1 and 4/3, disagreements between synthetic and experimental signals suggest that the sawtooth instability may be influencing RE dynamics. Furthermore, other sources of pitch angle scattering, not considered in this analysis, could help explain discrepancies between simulation and experiment.

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Section: Methodsmentioning

confidence: 95%

Experimental and synthetic measurements of polarized synchrotron emission from runaway electrons in Alcator C-Mod

et al. 2019

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“…The impact of including relativistic ICS effects ( ) compared to using ICS without the Møller/generalized Breit interaction ( ) or simply assuming a thermal plasma (•) is apparent. the partial screening effect, which has a direct dependence on the ion charge state distribution, according to Hesslow et al [21,36]. The physical importance is that enhanced pitch angle scattering would limit the energy of the O-point of the runaway vortex, which is responsible for a lower runaway energy but broader pitch distribution [37,38].…”

Section: Runaway-induced Ion Charge State Effectsmentioning

confidence: 99%

“…For each ion species in a specific charge state, which is denoted by subscript α, there is a unique mean excitation energy I α and bound electron density n eα . In fact, the standard treatment in runaway modeling is to incorporate the runaway slowing down due to excitation and ionization via a friction in the Fokker-Planck collision operator using the Bethe formula [20,21]. The effect of ion charge state distribution (CSD) on runaway and thermal bulk plasma evolu-tion is through a collisional-radiative (CR) model that deals with only the background Maxwellian population at given temperature.…”

mentioning

confidence: 99%

“…The effect of ion charge state distribution (CSD) on runaway and thermal bulk plasma evolu-tion is through a collisional-radiative (CR) model that deals with only the background Maxwellian population at given temperature. In a dilute plasma such as those in tokamak disruption, the aforementioned decoupled treatment of background thermal electrons and runaways [20,21] has a straightforward prediction for the radiative power loss as the bulk electrons are cooled to below a few eV. Namely, the background electron density drops precipitously due to cold thermal electron recombination with ions.…”

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confidence: 99%

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Impact of a minority relativistic electron tail interacting with a thermal plasma containing high-atomic-number impurities

Garland

Chung²,

Fontes

et al. 2020

Physics of Plasmas

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A minority relativistic electron component can arise in both laboratory and naturally-occurring plasmas. In the presence of high-atomic-number ion species, the ion charge state distribution at low bulk electron temperature can be dominated by relativistic electrons, even though their density is orders of magnitude lower. This is due to the relativistic enhancement of the collisional excitation and ionization cross sections. The resulting charge state effect can dramatically impact the radiative power loss rate and the related Bethe stopping power of relativistic electrons in a dilute plasma. (Approved for release under LA-UR-19-28749)

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“…with the deterministic trajectory obeying the ordinary differential equations dx/ds = v and dp/ds = µ. The integral (12) can be computed efficiently to high accuracy using Gauss-Hermite quadrature rules as demonstrated previously 28 . One should note that for each point z the values (X ∆s , P ∆s ) are needed only once regardless of how many intervals ∆s are used for the recursive computation.…”

Section: A the General Recipementioning

confidence: 99%

A fluid-kinetic framework for self-consistent runaway-electron simulations

et al. 2018

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The problem of self-consistently coupling kinetic runaway-electron physics to the macroscopic evolution of the plasma is addressed by dividing the electron population into a bulk and a tail. A probabilistic closure is adopted to determine the coupling between the bulk and the tail populations, preserving them both as genuine, non-negative distribution functions. Macroscopic one-fluid equations and the kinetic equation for the runaway-electron population are then derived, now displaying sink and source terms due to transfer of electrons between the bulk and the tail.

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Effect of Partially Screened Nuclei on Fast-Electron Dynamics

Cited by 58 publications

References 33 publications

Experimental and synthetic measurements of polarized synchrotron emission from runaway electrons in Alcator C-Mod

Experimental and synthetic measurements of polarized synchrotron emission from runaway electrons in Alcator C-Mod

Impact of a minority relativistic electron tail interacting with a thermal plasma containing high-atomic-number impurities

A fluid-kinetic framework for self-consistent runaway-electron simulations

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