Simulation of charged particles and discharges using transmission line modelling

A. K. Dinnis; T. M. Benson; C. Christopoulos; M. G. Kong

Simulation of charged particles and discharges using transmission line modelling

A. K. Dinnis
, T. M. Benson
, C. Christopoulos
, M. G. Kong

School of Chemical Engineering and Technology

University of Nottingham

Research output: Contribution to journal › Conference article › peer-review

Abstract

A numerical model for simulating charged particle interactions with electromagnetic fields in general configurations, including particle generation and recombination, is proposed. Space charge effects are included at each stage of the simulation. Ionization processes are introduced into the model by connecting current sources across appropriate points in the transmission line matrix to achieve separation, thereby generating charged pairs. Comparison of simulated results with experimental data in the literature confirms that the model correctly-predicts Townsend's first ionization coefficient, electron drift density, longitudinal and radial diffusion coefficients and the average energy of the electron swarm.

Original language	English
Pages (from-to)	308-309
Number of pages	2
Journal	IEEE International Conference on Plasma Science
State	Published - 1998
Event	Proceedings of the 1998 IEEE International Conference on Plasma Science - Raleigh, NC, USA Duration: 1 Jun 1998 → 4 Jun 1998

Cite this

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title = "Simulation of charged particles and discharges using transmission line modelling",

abstract = "A numerical model for simulating charged particle interactions with electromagnetic fields in general configurations, including particle generation and recombination, is proposed. Space charge effects are included at each stage of the simulation. Ionization processes are introduced into the model by connecting current sources across appropriate points in the transmission line matrix to achieve separation, thereby generating charged pairs. Comparison of simulated results with experimental data in the literature confirms that the model correctly-predicts Townsend's first ionization coefficient, electron drift density, longitudinal and radial diffusion coefficients and the average energy of the electron swarm.",

author = "Dinnis, \{A. K.\} and Benson, \{T. M.\} and C. Christopoulos and Kong, \{M. G.\}",

year = "1998",

language = "英语",

pages = "308--309",

journal = "IEEE International Conference on Plasma Science",

issn = "0730-9244",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

note = "Proceedings of the 1998 IEEE International Conference on Plasma Science ; Conference date: 01-06-1998 Through 04-06-1998",

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TY - JOUR

T1 - Simulation of charged particles and discharges using transmission line modelling

AU - Dinnis, A. K.

AU - Benson, T. M.

AU - Christopoulos, C.

AU - Kong, M. G.

PY - 1998

Y1 - 1998

N2 - A numerical model for simulating charged particle interactions with electromagnetic fields in general configurations, including particle generation and recombination, is proposed. Space charge effects are included at each stage of the simulation. Ionization processes are introduced into the model by connecting current sources across appropriate points in the transmission line matrix to achieve separation, thereby generating charged pairs. Comparison of simulated results with experimental data in the literature confirms that the model correctly-predicts Townsend's first ionization coefficient, electron drift density, longitudinal and radial diffusion coefficients and the average energy of the electron swarm.

AB - A numerical model for simulating charged particle interactions with electromagnetic fields in general configurations, including particle generation and recombination, is proposed. Space charge effects are included at each stage of the simulation. Ionization processes are introduced into the model by connecting current sources across appropriate points in the transmission line matrix to achieve separation, thereby generating charged pairs. Comparison of simulated results with experimental data in the literature confirms that the model correctly-predicts Townsend's first ionization coefficient, electron drift density, longitudinal and radial diffusion coefficients and the average energy of the electron swarm.

UR - https://www.scopus.com/pages/publications/0031636724

M3 - 会议文章

AN - SCOPUS:0031636724

SN - 0730-9244

SP - 308

EP - 309

JO - IEEE International Conference on Plasma Science

JF - IEEE International Conference on Plasma Science

T2 - Proceedings of the 1998 IEEE International Conference on Plasma Science

Y2 - 1 June 1998 through 4 June 1998

ER -

Simulation of charged particles and discharges using transmission line modelling

Abstract

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