Numerical modelling of negative discharges in air with experimental validation

Tran, T.N.; Golosnoy, Igor O.; Lewin, P.L.; Georghiou, George E.

doi:10.1088/0022-3727/44/1/015203

Cited by 151 publications

(121 citation statements)

References 31 publications

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“…The electron energy flux at the cathode and the anode is: electron density at t=0. The initial condition has been confirmed to only speed up the pulse formation and not to change the discharge characteristics [25,36].…”

Section: Boundary Conditions and Computational Implementationmentioning

confidence: 92%

“…These transport coefficients of electrons are obtained from solving the Boltzmann equation [25].The streamer discharge in air in highly overstressed gap is very fast (several nanoseconds). On the several nanoseconds time scale, the diffusion and mobility phenomenon of heavy species (ions and neutral particles) have almost no influence on the discharge propagation.…”

Section: N Nmentioning

confidence: 99%

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Numerical Simulation of the Characteristics of Electrons in Bar-plate DC Negative Corona Discharge Based on a Plasma Chemical Model

Liu¹,

Liao²,

Zhao³

2015

Journal of Electrical Engineering and Technology

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-In order to explore the characteristics of electrons in DC negative corona discharge, an improved plasma chemical model is presented for the simulation of bar-plate DC corona discharge in dry air. The model is based on plasma hydrodynamics and chemical models in which 12 species are considered. In addition, the photoionization and secondary electron emission effect are also incorporated within the model as well. Based on this model, electron mean energy distribution (EMED), electron density distribution (EDD), generation and dissipation rates of electron at 6 typical time points during a pulse are discussed emphatically. The obtained results show that, the maximum of electron mean energy (EME) appears in field ionization layer which moves towards the anode as time progresses, and its value decreases gradually. Within a pulse process, the electron density (ED) in cathode sheath almost keeps 0, and the maximum of ED appears in the outer layer of the cathode sheath. Among all reactions, R1 and R2 are regarded as the main process of electron proliferation, and R 22 plays a dominant role in the dissipation process of electron. The obtained results will provide valuable insights to the physical mechanism of negative corona discharge in air. Keywords: Corona discharge, Plasma chemical, Numerical simulation

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Section: Boundary Conditions and Computational Implementationmentioning

confidence: 92%

Section: N Nmentioning

confidence: 99%

Numerical Simulation of the Characteristics of Electrons in Bar-plate DC Negative Corona Discharge Based on a Plasma Chemical Model

Liu¹,

Liao²,

Zhao³

2015

Journal of Electrical Engineering and Technology

View full text Add to dashboard Cite

show abstract

“…The governing equations are expressed as follows by adding background ionization and photoionization term based on Tran's experiment. 24 ∂c e ∂t = c e α|W e | − c e η|W e | − c e c p β ep −∇ · (c e W e − D e ∇c e ) + S ph + S 0…”

Section: Model Description a Simulation Modelmentioning

confidence: 99%

Ion-impact secondary emission in negative corona with photoionization

Sun

2017

AIP Advances

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A corona discharge measurement system and simulation model are presented to investigate the effects of photoionization and ion-impact secondary emission process in negative corona discharge. The simulation results obtained is shown good agreement with experimental observations. Distribution of electron density along the symmetry axis at three critical moments is shown and the role of photoionization in negative corona discharge is clearly explained. Moreover, the current pulses are also presented under different secondary emission coefficients and the effect of the secondary emission coefficient is discussed.

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“…v e , v p , and v n are the drift velocities of electrons, positive ions, and negative ions, which can be obtained by [22]: 1 7 6 3.63 10 exp( 1.68 10 / ), 4.56 10 / 7.36 10 exp( 2 10 / ), 4.56 …”

Section: Governing Equationsmentioning

confidence: 99%

Space and Time Domain Finite Volume Method for Numerical Simulation of Negative Corona Discharge in Air

Wang¹

2016

Journal of Electrical Engineering and Technology

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-In this paper, a space and time domain finite volume method is proposed to study the characteristics of space charges on a bar-to-plate geometry. Three ionic species, namely, positive ions, negative ions, and electrons, are considered. A finite element method is used to solve Poisson's equation, and a finite volume method is used to solve charge transport equation. Different time steps based on space domain and time domain are applied to improve computational efficiency when solving the charge transport equation. Four points are marked to indicate the characteristics of a Trichel pulse. Density distributions of three ionic species and electrical field strength along the axis are presented. Trichel pulses on a bar-to-plate geometry are simulated and compared with the experimental results. Good agreements are obtained, thereby confirming the validity of the proposed method.

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Numerical modelling of negative discharges in air with experimental validation

Cited by 151 publications

References 31 publications

Numerical Simulation of the Characteristics of Electrons in Bar-plate DC Negative Corona Discharge Based on a Plasma Chemical Model

Numerical Simulation of the Characteristics of Electrons in Bar-plate DC Negative Corona Discharge Based on a Plasma Chemical Model

Ion-impact secondary emission in negative corona with photoionization

Space and Time Domain Finite Volume Method for Numerical Simulation of Negative Corona Discharge in Air

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