Investigation of the short argon arc with hot anode. I. Numerical simulations of non-equilibrium effects in the near-electrode regions

Khrabry, Alexander; Kaganovich, Igor; Nemchinsky, Valerian; Khodak, Andrei

doi:10.1063/1.5007082

Cited by 40 publications

(57 citation statements)

References 46 publications

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“…The plasma model was benchmarked in Ref. [42] by comparison to the results of previous numerical studies [41] and in Ref. 43 by comparison to analytical solutions.…”

Section: Arc Modelmentioning

confidence: 99%

Synthesis of nanoparticles in carbon arc: measurements and modeling

et al. 2018

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This work studies the region of nanoparticle growth in atmospheric pressure carbon arc.Detection of the nanoparticles is realized via the planar laser induced incandescence (PLII) approach.Measurements revealed large clouds of nanoparticles in the arc periphery, bordering the region with high density of diatomic carbon molecules. Two-dimensional computational fluid dynamic simulations of the arc combined with thermodynamic modeling explain these results due to interplay of the condensation of carbon molecular species and the convection flow pattern. The results have shown that the nanoparticles are formed in the colder, outside regions of the arc and described the parameters necessary for coagulation.

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“…The plasma model was benchmarked in Ref. [42] by comparison to the results of previous numerical studies [41] and in Ref. 43 by comparison to analytical solutions.…”

Section: Arc Modelmentioning

confidence: 99%

Synthesis of nanoparticles in carbon arc: measurements and modeling

et al. 2018

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“…Emission from the anode is not considered since it would get reflected promptly back to the anode in the inverse mode. (In classical and SCL modes, emission from the anode can enter the plasma and play a significant role discussed by Levko [38] and Khrabry et al [39]. )…”

Section: The Inverse Mode -Analytical Modelmentioning

confidence: 98%

Alternative model of space-charge-limited thermionic current flow through a plasma

Campanell

2018

Phys. Rev. E

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It is widely assumed that thermionic current flow through a plasma is limited by a "space-charge-limited" (SCL) cathode sheath that consumes the hot cathode's negative bias and accelerates upstream ions into the cathode. Here, we formulate a fundamentally different current-limited mode. In the "inverse" mode, the potentials of both electrodes are above the plasma potential, so that the plasma ions are confined. The bias is consumed by the anode sheath. There is no potential gradient in the neutral plasma region from resistivity or presheath. The inverse cathode sheath pulls some thermoelectrons back to the cathode, thereby limiting the circuit current. Thermoelectrons entering the zero-field plasma region that undergo collisions may also be sent back to the cathode, further attenuating the circuit current. In planar geometry, the plasma density is shown to vary linearly across the electrode gap. A continuum kinetic planar plasma diode simulation model is set up to compare the properties of current modes with classical, conventional SCL, and inverse cathode sheaths. SCL modes can exist only if charge-exchange collisions are turned off in the potential well of the virtual cathode to prevent ion trapping. With the collisions, the current-limited equilibrium must be inverse. Inverse operating modes should therefore be present or possible in many plasma devices that rely on hot cathodes. Evidence from past experiments is discussed. The inverse mode may offer opportunities to minimize sputtering and power consumption that were not previously explored due to the common assumption of SCL sheaths.

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“…In this section, system of transport equations describing species transport and heat transfer in the arc is presented. Full set of governing transport equations for the arc was already given in the first paper of this series 7 and in Ref. [22] with proper description and derivation.…”

Section: Basic Transport Equations In the Arc Modelmentioning

confidence: 99%

“…Parametric studies of the atmospheric pressure argon arc for various current densities and interelectrode gap sizes were performed in Ref. [7]. It was shown, in particular, that the different arc regions are rather autonomic even in case of short arcs (weakly depend on the arc length) and can be considered separately.…”

Section: Introductionmentioning

confidence: 99%

“…It was shown, in particular, that the different arc regions are rather autonomic even in case of short arcs (weakly depend on the arc length) and can be considered separately. Based on the results of the simulations performed and presented in the first paper 7 , the current study reports self-consistent analytic models of the near-electrode regions and the arc column combined into a unified self-consistent analytical model of the whole arc. Non-equilibrium processes in plasma and effects of near-electrode space-charge sheaths are taken into account.…”

Section: Introductionmentioning

confidence: 99%

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Investigation of the short argon arc with hot anode. II. Analytical model

et al. 2018

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Short atmospheric pressure argon arc is studied numerically and analytically. In a short arc with interelectrode gap of several millimeters non-equilibrium effects in plasma play important role in operation of the arc. High anode temperature leads to electron emission and intensive radiation from its surface. Complete self-consistent analytical model of the whole arc comprising of models for near-electrode regions, arc column and a model of heat transfer in cylindrical electrodes was developed. The model predicts width of non-equilibrium layers and arc column, voltages and plasma profiles in these regions, heat and ion fluxes to the electrodes. Parametric studies of the arc have been performed for a range of the arc current densities, inter-electrode gap widths and gas pressures. The model was validated against experimental data and verified by comparison with numerical solution. Good agreement between the analytical model and simulations and reasonable agreement with experimental data were obtained.

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Investigation of the short argon arc with hot anode. I. Numerical simulations of non-equilibrium effects in the near-electrode regions

Cited by 40 publications

References 46 publications

Synthesis of nanoparticles in carbon arc: measurements and modeling

Synthesis of nanoparticles in carbon arc: measurements and modeling

Alternative model of space-charge-limited thermionic current flow through a plasma

Investigation of the short argon arc with hot anode. II. Analytical model

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