Large-volume excitation of air, argon, nitrogen and combustible mixtures by thermal jets produced by nanosecond spark discharges

Stepanyan, Sergey; Hayashi, Jun; Salmon, Arthur; Stancu, Gabi-Daniel; Laux, Christophe O.

doi:10.1088/1361-6595/aa5a2b

Cited by 29 publications

(24 citation statements)

References 37 publications

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“…However, this recirculation does not occur before 1 µs, as can be clearly seen from Figure 5 of Ref. [45], obtained for discharge under similar conditions. Therefore, recirculation does not affect the decay of ne shown in Figure 13.…”

Section: Methodsmentioning

confidence: 54%

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Fully ionized nanosecond discharges in air: the thermal spark

Minesi

Stepanyan

Mariotto

et al. 2020

Plasma Sources Sci. Technol.

106

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The formation and decay of the thermal spark generated by a single nanosecond highvoltage pulse between pin electrodes are characterized in this study. The influence of air pressure in the range 50 -1000 mbar is investigated at 300 K. By performing short-gate imaging and Optical Emission Spectroscopy (OES), we find that the thermal sparks exhibit an intense emission from excited electronic states of N + , in contrast with non-thermal sparks for which the emission is dominated by electronic transitions of N2. Spark thermalization consists of the following steps: (i) partial ionization of the plasma channel accompanied by N2 emission, (ii) creation of a fully ionized filament at the cathode characterized by N + emission, (iii) formation of a fully ionized filament at the anode, (iv) propagation of these filaments toward the middle of the interelectrode gap, and (v) merging of the filaments. The formation of the filaments, steps (ii) and (iii), occurs at subnanosecond timescales. The propagation speed of the filaments is on the order of 10 4 m/s during step (iv). For the 1-bar condition, the electron number densities are measured from the Stark broadening of N + and Hα lines, with spatial and temporal resolution. The electron temperature is also determined, from the relative emission intensity of N + excited states, attaining a peak value of 48,000 K. In the post-discharge, the electron number density decays from 4×10 19 to 2×10 18 cm -3 in 100 ns. We show that this decay curve can be interpreted as the isentropic expansion of a plasma in chemical equilibrium. Comparisons with previous experiments from the literature support this conclusion. Expressions for the Van der Waals and resonant broadenings of H, Hβ, and several lines of O, O + , N and, N + are derived in the appendix.

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Section: Methodsmentioning

confidence: 54%

“…At longer timescales (t > 1 μs), hydrodynamic effects lead to the formation of a torus and the mixing of the plasma column with fresh gas [45][46][47][48][49]. In the numerical study of Ref.…”

Section: Methodsmentioning

confidence: 99%

Fully ionized nanosecond discharges in air: the thermal spark

Minesi

Stepanyan

Mariotto

et al. 2020

Plasma Sources Sci. Technol.

106

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“…It should be noted that for different pin-electrodes (i.e. for various pin-tip radii of curvature) no difference was observed, neither in the energy deposition nor in the hydrodynamic effects induced by the plasma [37]. So the results presented here for pin-to-pin geometry can be considered to be quite general.…”

Section: Methodsmentioning

confidence: 53%

“…The same dependence of the energy deposition on the burst frequency is observed for pure argon and oxygen (see figure 2g. As the result the discharges initiated in these gases induce hydrodynamic affects at similar temporal and spatial scales, as demonstrated in [37].…”

Section: Resultsmentioning

confidence: 81%

“…Therefore, the average density was 0.2 mJ/mm 3 for the 2-mm gap and 0.1 mJ/mm 3 for the 7-mm gap. It should be noted that both cases correspond to volumes that are significantly larger that the ignition kernel produced by a conventional spark ignition system (for more details see [37]), whereas the volumetric energy density is still sufficient for ignition of combustible mixtures. Thus NRP can be considered as an efficient tool to redistribute spatially the energy deposited in the plasma during a period shorter than a typical ignition delay time.…”

Section: Resultsmentioning

confidence: 99%

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Hydrodynamic effects induced by nanosecond repetitive pulsed discharges

Stepanyan

Minesi

Pannier

et al. 2018

2018 AIAA Aerospace Sciences Meeting

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The intense energy released in a burst of nanosecond sparks is shown to induce hydrodynamic effects over large spatial scales of the order of a centimeter. This gas motion transports the active species produced by the discharge into the surrounding space. The present work is dedicated to the detailed measurements of the energy deposited in plasma and its redistribution in space through hydrodynamic degrees of freedom.

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