Intense boundary emission destroys normal radio-frequency plasma sheath

Sun, Guangyu; Sun, Anbang; Zhang, Guanjun

doi:10.1103/physreve.101.033203

Cited by 14 publications

(17 citation statements)

References 84 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The first term in RHS of Equation ( 17) is hence negative. The derivative 𝜕𝛾 𝑒 𝜕𝜑 𝑠ℎ is further expressed as follows combining Equations ( 10), (13): (18) Note that 𝜎 𝑤𝑎𝑙𝑙 < 0 in the present analyses. If a constant plasma electron temperature is assumed, which is true for the present simulation but may vary in practical discharges, the RHS of Equation ( 18) should be positive since 𝜕𝜎 𝑤𝑎𝑙𝑙 𝜕𝜑 𝑠ℎ < 0.…”

Section: Combined See Model and Analyses Of Sheath Stabilitymentioning

confidence: 99%

“…PIC model where self-consistent plasma-neutral collisions are implemented. A comparison of the kinetic simulation and PIC simulation was recently performed for the capacitively-coupled plasma subject to strong electron emission from the boundary (13,35), where discrepancies are more obvious at high neutral pressure levels as the kinetic model does not implement realistic electron-neutral collisions and ionization sources. Similar comparison between kinetic and PIC model of the SEE coefficient charging effect are expected for DC or RF plasma conditions.…”

Section: Implementation Of Electron Backscattering In Simulationmentioning

confidence: 99%

“…In this section, employed simulation algorithms and typical simulation results are presented. The simulation model is inspired by previous Vlasov-Poisson solvers [11,15], and a basic version of the code was used in our recent simulations [13,20,21]. The employed 1D1V kinetic simulation code is based on the following kinetic equation:…”

Section: Simulation Setupmentioning

confidence: 99%

“…More recent studies suggested that the SCL sheath cannot remain stable if cold ions are generated by charge exchange collisions in the sheath [11]. The emissive sheath is difficult to be directly accessed by conventional probe diagnostics due to its small size, so sheath theories are frequently validated against numerical simulations [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

“…Simulation setup In this section, employed simulation algorithms and typical simulation results are presented. The simulation model is inspired by previous Vlasov-Poisson solvers (11,15), and a basic version of the code was used in our recent simulations (13,20,21). The employed 1D1V kinetic simulation code is based on the following kinetic equation: Here the subscript s represents species, 𝑚 𝑠 , 𝑞 𝑠 , 𝑣 𝑠 are mass, charge and velocity of the species, 𝐸 is the electric field and the RHS is the collision-source term.…”

mentioning

confidence: 99%

See 4 more Smart Citations

Vlasov simulation of the emissive plasma sheath with energy-dependent secondary emission coefficient and improved modeling for dielectric charging effects

et al. 2022

Self Cite

View full text Add to dashboard Cite

A one-dimensional Vlasov–Poisson simulation code is employed to investigate the plasma sheath considering electron-induced secondary electron emission (SEE) and backscattering. The SEE coefficient is commonly treated as constant in a range of plasma simulations; here, an improved SEE model of a charged dielectric wall is constructed, which includes the wall charging effect on the SEE coefficient and the energy dependency of the SEE coefficient. Pertinent algorithms to implement the previously mentioned SEE model in plasma simulation are studied in detail. It is found that the SEE coefficient increases with the amount of negative wall charges, which in turn reduces the emissive sheath potential. With an energy-dependent SEE coefficient, the sheath potential is a nonlinear function of the plasma electron temperature, as opposed to the linear relation predicted by the classic emissive sheath theory. Simulation combining both wall-charging effect and SEE coefficient’ energy dependency suggests that the space-charged limited sheath is formed at high plasma electron temperature levels, where both sheath potential and surface charging saturate. Additionally, different algorithms to implement the backscattering in the kinetic simulation are tested and compared. Converting backscattered electrons to secondary electrons via an effective SEE coefficient barely affects the sheath properties. The simulation results are shown to be commensurate with the upgraded sheath theory predictions.

show abstract

Section: Combined See Model and Analyses Of Sheath Stabilitymentioning

confidence: 99%

Section: Implementation Of Electron Backscattering In Simulationmentioning

confidence: 99%

Section: Simulation Setupmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

See 3 more Smart Citations

Vlasov simulation of the emissive plasma sheath with energy-dependent secondary emission coefficient and improved modeling for dielectric charging effects

et al. 2022

Self Cite

View full text Add to dashboard Cite

show abstract

Development of an arc root model for studying the electrode vaporization and its influence on arc dynamics

et al. 2020

View full text Add to dashboard Cite

Plasma–solid interaction represents a major concern in many applications such as power-interruption and plasma–metal processing. Characterized by high-current density and voltage drop, the arc roots dissipate intensive heat to electrode vaporization, which participates in the ionization and, thereby, significantly alters the plasma properties and gas dynamics. Most of the arc root models feature approaches based on surface temperature or (temperature dependent) current density. Due to the complexity of conjugated heat transfer across arc roots involving three-phase interactions of plasma with liquid spots and solid electrodes, accurately determining the surface temperature distribution is extremely computationally demanding. Hence, models hitherto fail to quantitatively estimate neither the molten spot size nor the total amount of vaporization. In this work, we propose an arc root model featuring a hemispherical structure that correlates the molten spot size with the heat partition between conduction and vaporization to estimate the energy dissipation at arc roots and, thus, to trace the vaporization rate. Following local partial pressure adjusted Langmuir vaporization, we deduce an analytical solution of molten spot size for quasi-steady-state, which compares favorably with experiments. Specifically, the vaporization dominates over conduction for large molten spots as in the case of high-current arcs. However, for low-current arcs, the vaporization heat is trivial compared with conduction. Furthermore, we integrate this arc root model into a study case of arc plasma based on the magnetohydrodynamics method. The simulated arc voltage and arc displacement match with the experiment. This model is expected to find broad applications in power interruption and plasma etching.

show abstract

Particle modeling of vacuum arc discharges

Yang

Sun

Zhou

2020

Journal of Applied Physics

View full text Add to dashboard Cite

Metal vapor vacuum arcs (VAs) are widely used in various fields of industry, such as circuit breakers, ion sources, electrical thrusters, and deposition systems. VAs usually originate from metal vapors eroding from the surface of a cathode, where they burn as tiny bright points, hence their name “cathode spots” (CS). Due to their high plasma density, short life span, and micrometer scale, the in situ and non-intrusive diagnostics of CS are a challenge. Numerical simulation is one method used to study CS with the aid of high-performance computing. The well-established particle-in-cell method provides solutions for the spatial-temporal electromagnetic field and the microscopic distribution functions of plasma species in phase space from which the macroscopic parameters of the plasma can be calculated. This Perspective reviews the progress in particle modeling of VAs with an emphasis on the non-stationary and non-local physical processes that are not reproduced by fluid models. Furthermore, a personal outlook on future challenges is provided: the physical modeling of plasma–electrode interactions, the collection and evaluation of collision cross sections, the trade-off between heavy computation cost and predictive ability, and the verification and validation of the simulation code.

show abstract

Intense boundary emission destroys normal radio-frequency plasma sheath

Cited by 14 publications

References 84 publications

Vlasov simulation of the emissive plasma sheath with energy-dependent secondary emission coefficient and improved modeling for dielectric charging effects

Vlasov simulation of the emissive plasma sheath with energy-dependent secondary emission coefficient and improved modeling for dielectric charging effects

Development of an arc root model for studying the electrode vaporization and its influence on arc dynamics

Particle modeling of vacuum arc discharges

Contact Info

Product

Resources

About