Effect of the magnetic field on the electron kinetics under AC/DC electric fields: benchmark calculations and electron cyclotron resonance

Dias, Tiago C; Pintassilgo, Carlos D; Guerra, Vasco

doi:10.1088/1361-6595/acf343

Cited by 3 publications

(2 citation statements)

References 50 publications

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“…In the paper [43] it was shown that for argon there is a range of reduced electric fields and a constant value of the magnetic field, the average electron energy decreases with the electric field increasing. A similar effect also was studied in later works (for example, [44,45]).…”

Section: Introductionsupporting

confidence: 72%

Two-term Boltzmann approximation versus Monte-Carlo simulation: effect of magnetic field

Tereshonok,

Chernyshev,

Abramov

et al. 2024

Phys. Scr.

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In this paper, we investigate the spatial-local electron energy distribution function (eEDF) interacting with a backgroundgas at the sub-atmospheric pressure in a wide range of applied crossed electric and magnetic fields using the Boltzmannkinetic equation. We compare solutions obtained using two numerical approaches (deterministic two-term approximation andstochastic Monte Carlo method) to identify their applicability in the context of determining drift velocity and reaction constantsfor electrons. For argon and helium, the upper limit of the reduced electric field applicability of the two-term approximationis discussed. It has been shown that the presence of a magnetic field can reduce this limit. Two explanations are given, oneis based on the math of two-term formalism, and the other is based on velocity-space analysis. Two-term approximation failsdue to it’s inability to resolve underlying cyclotron oscillation (it should result in an energy variation along the electron’strajectory). The absence of this feature causes an incorrect estimation of momentum-transfer rate. This results an inaccuracyin the estimation of the angle between electric field and drift velocity.

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Section: Introductionsupporting

confidence: 72%

Two-term Boltzmann approximation versus Monte-Carlo simulation: effect of magnetic field

Tereshonok,

Chernyshev,

Abramov

et al. 2024

Phys. Scr.

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show abstract

“…Studies of plasma properties under the joint action of electric and magnetic fields are of great interest for a broad range of applications, including plasma propulsion, magnetron sputtering, magneto-hydrodynamic flow control and power generation, plasma processing techniques for thin-film deposition and surface modification, among others. The effects of applied magnetic fields on the kinetics and transport properties of electrons [1][2][3] and on the characteristics of discharges of various types ( [4][5][6][7][8][9] and references therein) are actively studied. One of the important effects is the influence of applied magnetic fields on discharge inception and breakdown voltages [10].…”

Section: Introductionmentioning

confidence: 99%

Inception of positive wire-cylinder corona discharges in air in crossed electric and magnetic fields

Naidis

2024

J. Phys. D: Appl. Phys.

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Computational study of inception of positive wire-cylinder corona discharges in low-pressure air in crossed electric and magnetic fields is performed. The inception voltages are calculated for a wide range of gas densities, wire radii and applied magnetic fields. Conditions are considered when the reduced electric fields at wire electrodes reach extremely high values, of about 10 kTd. Expression, applicable at such strong fields, for the ionization coefficient, the key parameter of the corona inception model, is presented versus the values of electric and magnetic fields. Calculated inception voltages agree with a number of available experimental data on low-pressure positive corona discharges, obtained both with and without application of magnetic fields. Results of calculation describe specific details of non-monotonous dependence of the inception voltages on the magnetic field values, similar to those obtained in experiments.

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Behavior of plasma parameters under mirror and cusp magnetic fields in DC glow discharge – a numerical study

M S,

V R,

Ramachandran

2024

Phys. Scr.

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The plasma parameters in DC glow discharge can easily be controlled by externally applied magnetic field without disturbing internal / built-in process parameters. Though several works have been carried out to study the influence of the magnetic field at different configurations on the plasma parameters, a complete understanding on the behaviour of the plasma discharge under the mirror and cusp fields could not be achieved. Further studies on the same are needed to improve the efficiency of the DC glow discharge system for existing applications and to find the new applications. In this work, a 2D axis-symmetric non-equilibrium plasma model with drift-diffusion approach is developed to study the characteristics of the plasma in DC glow discharge through various plasma parameters under mirror and cusp fields. The effects of current and position of magnetic coils on electric potential, ionization rate, electron temperature and electron number density are predicted and discussed. The distribution of electron number density at various coil currents and positions under both mirror and cusp fields are presented and the operating conditions favorable for applications in surface modification are suggested.

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Effect of the magnetic field on the electron kinetics under AC/DC electric fields: benchmark calculations and electron cyclotron resonance

Cited by 3 publications

References 50 publications

Two-term Boltzmann approximation versus Monte-Carlo simulation: effect of magnetic field

Two-term Boltzmann approximation versus Monte-Carlo simulation: effect of magnetic field

Inception of positive wire-cylinder corona discharges in air in crossed electric and magnetic fields

Behavior of plasma parameters under mirror and cusp magnetic fields in DC glow discharge – a numerical study

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