A. C. Denig scite author profile

In this paper we propose a representative simulation test-case of E × B discharges accounting for plasma wall interactions with the presence of both the Electron Cyclotron Drift Instability (ECDI) and the Modified-Two-Stream-Instability (MTSI). Seven independently developed Particle-In-Cell (PIC) codes have simulated this benchmark case, with the same specified conditions. The characteristics of the different codes and computing times are given. Results show that both instabilities were captured in a similar fashion and good agreement between the different PIC codes is reported as main plasma parameters were closely related within a 5% interval. The number of macroparticles per cell was also varied and statistical convergence was reached. Detailed outputs are given in the supplementary data, to be used by other similar groups in the perspective of code verification.

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Low-enriched cermet-based fuel options for a nuclear thermal propulsion engine

Gates

Denig

Ahmed

et al. 2018

Nuclear Engineering and Design

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Three-dimensional coupling of electron cyclotron drift instability and ion–ion two stream instability

Denig

Hara

2023

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Electron cyclotron drift instability (ECDI) and ion–ion two stream instability (IITSI) are both kinetic instabilities that can be present in low-temperature, partially magnetized plasmas. The coupling of instabilities in a three-dimensional configuration leads to the existence of more than one unstable roots to the kinetic dispersion relation. In this paper, a generalized method has been developed for numerically evaluating solutions to the three-dimensional dispersion relation for coupled ECDI and IITSI, assuming cold singly and doubly charged ions and a Maxwellian velocity distribution function for the electrons. The present study demonstrates the coupling between ECDI and IITSI that affects the most unstable mode as a function of the wavenumbers in three dimensions and various plasma properties, including the applied electric field, magnetic field, electron temperature, ion velocities, and plasma density. One of the most notable results is that, while the most unstable mode with the largest growth rate is in the direction of the [Formula: see text] drift in the two-dimensional cases, the most unstable mode for the three-dimensional configuration occurs in the oblique direction between the applied electric field and the [Formula: see text] drift. This agrees with experimental observations in cross field plasma sources using coherent Thomson scattering.

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Monte Carlo–Informed Decay Heat Model for Cermet LEU-NTP Systems

Denig

Eades

2020

Nuclear Technology

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Three-Dimensional Coupling of Electron Cyclotron Drift Instability and Ion-Ion Two Stream Instability

Denig

Hara

Tsikata

2021

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A. C. Denig

2D radial-azimuthal particle-in-cell benchmark for E × B discharges

Low-enriched cermet-based fuel options for a nuclear thermal propulsion engine

Three-dimensional coupling of electron cyclotron drift instability and ion–ion two stream instability

Monte Carlo–Informed Decay Heat Model for Cermet LEU-NTP Systems

Three-Dimensional Coupling of Electron Cyclotron Drift Instability and Ion-Ion Two Stream Instability

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