A Kinetic Approach to the study of Ideal Multipole Resonance Probe

Junbo Gong; Sebastian Wilczek; Jens Oberrath; Denis Eremin; Michael Friedrichs; Ralf Peter Brinkmann

A Kinetic Approach to the study of Ideal Multipole Resonance Probe

Research output: Journal contributions › Conference abstract in journal › Research › peer-review

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A Kinetic Approach to the study of Ideal Multipole Resonance Probe. / Gong, Junbo; Wilczek, Sebastian; Oberrath, Jens et al.

In: Bulletin of the American Physical Society, Vol. 62, No. 10, DT2.00002, 2017, p. 6.

Research output: Journal contributions › Conference abstract in journal › Research › peer-review

Bibtex

@article{15f5d00295234c4483c53e06aa2a68a1,

title = "A Kinetic Approach to the study of Ideal Multipole Resonance Probe",

abstract = "Active Plasma Resonance Spectroscopy (APRS) denotes a class of industry-compatible plasma diagnostic methods which utilize the natural ability of plasmas to resonate on or near the electron plasma frequency. One particular realization of APRS with a high degree of geometric and electric symmetry is Multipole Resonance Probe (MRP). The Ideal MRP (IMRP) is an even more symmetric idealization which is suited for theoretical investigations. In this work, a spectral kinetic scheme is presented to investigate the behavior of the IMRP in the low pressure regime. The scheme consists of two modules, the particles pusher and the field solver. The particle pusher integrates the equations of motion for the studied particles. The Poisson solver determines the electric field at each particle position. The fluid model is studied to provide the initial conditions of simulation for optimization reason. The proposed method overcomes the limitation of the cold plasma model and covers kinetic effects like collisionless damping.",

keywords = "Engineering, active plasma resonance spectroscopy, multipole resonance probe",

author = "Junbo Gong and Sebastian Wilczek and Jens Oberrath and Denis Eremin and Michael Friedrichs and Brinkmann, {Ralf Peter}",

year = "2017",

language = "English",

volume = "62",

pages = "6",

journal = "Bulletin of the American Physical Society",

issn = "0003-0503",

publisher = "American Physical Society",

number = "10",

}

RIS

TY - JOUR

T1 - A Kinetic Approach to the study of Ideal Multipole Resonance Probe

AU - Gong, Junbo

AU - Wilczek, Sebastian

AU - Oberrath, Jens

AU - Eremin, Denis

AU - Friedrichs, Michael

AU - Brinkmann, Ralf Peter

PY - 2017

Y1 - 2017

N2 - Active Plasma Resonance Spectroscopy (APRS) denotes a class of industry-compatible plasma diagnostic methods which utilize the natural ability of plasmas to resonate on or near the electron plasma frequency. One particular realization of APRS with a high degree of geometric and electric symmetry is Multipole Resonance Probe (MRP). The Ideal MRP (IMRP) is an even more symmetric idealization which is suited for theoretical investigations. In this work, a spectral kinetic scheme is presented to investigate the behavior of the IMRP in the low pressure regime. The scheme consists of two modules, the particles pusher and the field solver. The particle pusher integrates the equations of motion for the studied particles. The Poisson solver determines the electric field at each particle position. The fluid model is studied to provide the initial conditions of simulation for optimization reason. The proposed method overcomes the limitation of the cold plasma model and covers kinetic effects like collisionless damping.

AB - Active Plasma Resonance Spectroscopy (APRS) denotes a class of industry-compatible plasma diagnostic methods which utilize the natural ability of plasmas to resonate on or near the electron plasma frequency. One particular realization of APRS with a high degree of geometric and electric symmetry is Multipole Resonance Probe (MRP). The Ideal MRP (IMRP) is an even more symmetric idealization which is suited for theoretical investigations. In this work, a spectral kinetic scheme is presented to investigate the behavior of the IMRP in the low pressure regime. The scheme consists of two modules, the particles pusher and the field solver. The particle pusher integrates the equations of motion for the studied particles. The Poisson solver determines the electric field at each particle position. The fluid model is studied to provide the initial conditions of simulation for optimization reason. The proposed method overcomes the limitation of the cold plasma model and covers kinetic effects like collisionless damping.

KW - Engineering

KW - active plasma resonance spectroscopy

KW - multipole resonance probe

UR - http://meetings.aps.org/Meeting/GEC17/Session/DT2.2

M3 - Conference abstract in journal

VL - 62

SP - 6

JO - Bulletin of the American Physical Society

JF - Bulletin of the American Physical Society

SN - 0003-0503

IS - 10

M1 - DT2.00002

ER -

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