Runaway of electrons in dense gases and mechanism of generation of high-power subnanosecond beams

Ткачев, А. Н.; Yakovlenko, S. I.

doi:10.2478/bf02475565

Cited by 14 publications

(1 citation statement)

References 47 publications

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“…The ionization rates in the cathode sheath, however, are negligible since it is essentially free of electrons. It has been shown that runaway ionization processes are dominant only in very short gaps and at low pressures even in extremely high electric fields [31,32]. Hence, for conditions considered in this study, the electron-impact transport and reaction coefficients provided by BOLSIG are sufficiently accurate.…”

Section: Theoretical Frameworkmentioning

confidence: 78%

Multi-scale modelling of pulsed nanosecond dielectric barrier plasma discharges in plane-to-plane geometry

Nagaraja¹,

Yang²,

Adamovich³

2013

J. Phys. D: Appl. Phys.

117

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An integrated theoretical and numerical framework is developed to study the dynamics of energy coupling, gas heating and generation of active species by repetitively pulsed nanosecond dielectric barrier discharges (NS DBDs) in air. The work represents one of the first attempts to simulate, in a self-consistent manner, multiple (more than 100) nanosecond pulses. Detailed information is obtained about the electric-field transients during each voltage pulse, and accumulation of plasma generated species and gas heating over ms timescales. The plasma is modelled using a two-temperature, detailed chemistry scheme, with ions and neutral species in thermal equilibrium at the gas temperature, and electrons in thermal nonequilibrium. The analysis is conducted with pressures and pulsing frequency in the range 40-100 Torr and 1-10 5 Hz, respectively. The input electrical energy is directly proportional to the number density, and remains fairly constant on a per molecule basis from pulse to pulse. Repetitive pulsing results in uniform production of atomic oxygen in the discharge volume via electron-impact dissociation during voltage pulses, and through quenching of excited nitrogen molecules in the afterglow. The ion Joule effect causes rapid gas heating of ∼40 K/pulse in the cathode sheath and generates weak acoustic waves. Conductive heat loss to the walls during the time interval between voltage pulses prevents overheating of the cathode layer and development of ionization instabilities. A uniform 'hat-shaped' temperature profile develops in the discharge volume after multiple pulses, due to chemical heat release from quenching of excited species. This finding may explain experimentally observed volumetric ignition (as opposed to hot-spot ignition) in fuel-air mixtures subject to NS DBD.

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Section: Theoretical Frameworkmentioning

confidence: 78%

Multi-scale modelling of pulsed nanosecond dielectric barrier plasma discharges in plane-to-plane geometry

Nagaraja¹,

Yang²,

Adamovich³

2013

J. Phys. D: Appl. Phys.

117

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Тарасенко

Yakovlenko

2006

PHYS-USP

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Electric Field in a Plasma Channel in a High-Pressure Nanosecond Discharge in Hydrogen: A Coherent Anti-Stokes Raman Scattering Study

2013

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Experimental results of a study of the electric field in a plasma channel produced during nanosecond discharge at a H2 gas pressure of (2-3)×10(5) Pa by the coherent anti-Stokes scattering method are reported. The discharge was ignited by applying a voltage pulse with an amplitude of ∼100 kV and a duration of ∼5 ns to a blade cathode placed at a distance of 10 and 20 mm from the anode. It was shown that this type of gas discharge is characterized by the presence of an electric field in the plasma channel with root-mean-square intensities of up to 30 kV/cm. Using polarization measurements, it was found that the direction of the electric field is along the cathode-anode axis.

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Runaway of electrons in dense gases and mechanism of generation of high-power subnanosecond beams

Cited by 14 publications

References 47 publications

Multi-scale modelling of pulsed nanosecond dielectric barrier plasma discharges in plane-to-plane geometry

Multi-scale modelling of pulsed nanosecond dielectric barrier plasma discharges in plane-to-plane geometry

Untitled

Electric Field in a Plasma Channel in a High-Pressure Nanosecond Discharge in Hydrogen: A Coherent Anti-Stokes Raman Scattering Study

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