Structure of nonlocal gradient-drift instabilities in Hall E × B discharges

Ivan Romadanov; Andrei Smolyakov; Yevgeny Raitses; Igor Kaganovich; Tang Tian; Sergei Ryzhkov

doi:10.1063/1.4971816

Structure of nonlocal gradient-drift instabilities in Hall E × B discharges

Ivan Romadanov
, Andrei Smolyakov
, Yevgeny Raitses
, Igor Kaganovich
, Tang Tian
, Sergei Ryzhkov

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

30 Scopus citations

Abstract

Gradient-drift (collisionless Simon-Hoh) instability is a robust instability often considered to be important for Hall plasma discharges supported by the electron current due to the E × B drift. Most of the previous studies of this mode were based on the local approximation. Here, we consider the nonlocal model which takes into account the electron inertia as well as the effects of the entire profiles of plasma parameters such as the electric, magnetic fields, and plasma density. Contrary to local models, nonlocal analysis predicts multiple unstable modes, which exist in the regions, where local instability criteria are not satisfied. This is especially pronounced for the long wavelength modes which provide larger contribution to the anomalous transport.

Original language	English (US)
Article number	122111
Journal	Physics of Plasmas
Volume	23
Issue number	12
DOIs	https://doi.org/10.1063/1.4971816
State	Published - Dec 1 2016

All Science Journal Classification (ASJC) codes

Condensed Matter Physics

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10.1063/1.4971816

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abstract = "Gradient-drift (collisionless Simon-Hoh) instability is a robust instability often considered to be important for Hall plasma discharges supported by the electron current due to the E × B drift. Most of the previous studies of this mode were based on the local approximation. Here, we consider the nonlocal model which takes into account the electron inertia as well as the effects of the entire profiles of plasma parameters such as the electric, magnetic fields, and plasma density. Contrary to local models, nonlocal analysis predicts multiple unstable modes, which exist in the regions, where local instability criteria are not satisfied. This is especially pronounced for the long wavelength modes which provide larger contribution to the anomalous transport.",

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AU - Romadanov, Ivan

AU - Smolyakov, Andrei

AU - Raitses, Yevgeny

AU - Kaganovich, Igor

AU - Tian, Tang

AU - Ryzhkov, Sergei

PY - 2016/12/1

Y1 - 2016/12/1

N2 - Gradient-drift (collisionless Simon-Hoh) instability is a robust instability often considered to be important for Hall plasma discharges supported by the electron current due to the E × B drift. Most of the previous studies of this mode were based on the local approximation. Here, we consider the nonlocal model which takes into account the electron inertia as well as the effects of the entire profiles of plasma parameters such as the electric, magnetic fields, and plasma density. Contrary to local models, nonlocal analysis predicts multiple unstable modes, which exist in the regions, where local instability criteria are not satisfied. This is especially pronounced for the long wavelength modes which provide larger contribution to the anomalous transport.

AB - Gradient-drift (collisionless Simon-Hoh) instability is a robust instability often considered to be important for Hall plasma discharges supported by the electron current due to the E × B drift. Most of the previous studies of this mode were based on the local approximation. Here, we consider the nonlocal model which takes into account the electron inertia as well as the effects of the entire profiles of plasma parameters such as the electric, magnetic fields, and plasma density. Contrary to local models, nonlocal analysis predicts multiple unstable modes, which exist in the regions, where local instability criteria are not satisfied. This is especially pronounced for the long wavelength modes which provide larger contribution to the anomalous transport.

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JF - Physics of Plasmas

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ER -

Structure of nonlocal gradient-drift instabilities in Hall E × B discharges

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