Rapid formation of electric field profiles in repetitively pulsed high-voltage high-pressure nanosecond discharges

Ito, Tsuyohito; Kobayashi, Kazunobu; Czarnetzki, Uwe; Hamaguchi, Satoshi

doi:10.1088/0022-3727/43/6/062001

Cited by 66 publications

(47 citation statements)

References 17 publications

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“…It is set at 0 V between t = 0 ns and t = 5 ns, increases linearly with time from t = 5 ns, peaks at t = 10 ns, then decreases with time linearly, and vanishes at t = 15 ns. This voltage variation is similar to what has been observed experimentally [3]. The electrode-gap distance is 1.2 mm.…”

supporting

confidence: 89%

“…This propagation occurs before the applied voltage peaks at t = 10 ns and lasts for a duration of about 1 ns. The simulation results and experimental observations [3] are found to be in good agreement.The temporal evolution of the electron-energy probability function (EEPF) [7] near the cathode (averaged over the region of 0-0.3 mm away from the cathode) is shown in Fig. 2.…”

supporting

confidence: 68%

“…The electrode-gap distance is 1.2 mm. The neutral gas is assumed to be molecular hydrogen (H 2 ) at room temperature and have a pressure of 0.3 atm, following the experimental conditions in [3].A uniformly distributed plasma with a plasma density of 10 10 cm −3 at 300 K is assumed to exist at t = 0. It represents Manuscript a remnant of the previous pulsed discharge.…”

mentioning

confidence: 99%

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Dynamics of Near-Atmospheric-Pressure Hydrogen Plasmas Driven by Pulsed High Voltages

Hamaguchi

2011

IEEE Trans. Plasma Sci.

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The formation mechanism of hydrogen plasmas by nanosecond high-voltage pulses at near-atmospheric pressure was examined by particle-in-cell/Monte-Carlo-collision simulations. In the model system, plasmas were generated between parallel metal electrodes. The simulation results show the propagation of ionization fronts and the formation of non-Maxwellian electron-energy distributions. The time evolution of plasma dynamics observed in the simulations has been confirmed to be in good agreement with recent experimental results.Index Terms-Atmospheric-pressure plasmas, nanosecondpulsed discharge, plasma simulation. P LASMAS have been widely used in many fields of industrial applications. Conventionally, these applications are operated under low-pressure conditions; therefore, materials that can be treated by such plasmas have been limited to those that can be placed in a vacuum chamber. For nonconventional applications, plasmas under higher pressure have become recently an important research topic. High-voltage short pulses are often used to generate such plasmas. Plasmas generated under such conditions are of low temperature and highly collisional.In this paper, we have examined the processes of hydrogenplasma formation by the application of repetitive high-voltage short pulses to parallel metal plates, using a 1-D-in-space and 2-D-in-velocity particle-in-cell (PIC) simulation [1] with Monte Carlo collisions (MCC) and a null-collision operator [2]. The simulation code was developed by the authors.In the simulation model, a plasma is generated between a grounded anode and a cathode connected to an external voltage source. The applied voltage is a triangular pulse with a peak value of −2 kV. It is set at 0 V between t = 0 ns and t = 5 ns, increases linearly with time from t = 5 ns, peaks at t = 10 ns, then decreases with time linearly, and vanishes at t = 15 ns. This voltage variation is similar to what has been observed experimentally [3]. The electrode-gap distance is 1.2 mm. The neutral gas is assumed to be molecular hydrogen (H 2 ) at room temperature and have a pressure of 0.3 atm, following the experimental conditions in [3].A uniformly distributed plasma with a plasma density of 10 10 cm −3 at 300 K is assumed to exist at t = 0. It represents Manuscript a remnant of the previous pulsed discharge. Numerically, the initial plasma, consisting of ions and electrons, is modeled by 20 000 simulation particles for each species. The charged species of the plasma are assumed to be only electrons and H + 3 ions. The processes of electron-neutral collisions considered are elastic collisions, ionization to H + 2 (because most H + 2 ions encounter collisions with neutral atoms and turn into H + 3 ions immediately under high-pressure conditions), the vibrational excitation of ν = 0 → 1, and electronic excitations to b 3 Σ + u , B 1 Σ + u , and E, F 1 Σ + g states. Three types of ion-neutral collisions are taken into account: momentum transfer, slow H + 3 production, and H + 3 annihilation. The collision cross-sectional data fo...

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supporting

confidence: 89%

supporting

confidence: 68%

mentioning

confidence: 99%

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Dynamics of Near-Atmospheric-Pressure Hydrogen Plasmas Driven by Pulsed High Voltages

Hamaguchi

2011

IEEE Trans. Plasma Sci.

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“…The main parameters determined directly are the discharge voltage, the current density, the electric field in the centre of the discharge, and the spatially and temporally resolved emission. First successful application of these diagnostics to a similar setup was reported in [1][2][3]. Here we go beyond by more detailed studies and in particular a careful analysis and interpretation of the data.…”

mentioning

confidence: 86%

Ignition of a nanosecond-pulsed near atmospheric pressure discharge in a narrow gap

Muller¹,

Luggenhölscher²,

Czarnetzki³

2011

J. Phys. D: Appl. Phys.

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“…[1][2][3] Despite the small size of these devices, state-ofthe-art diagnostics methods have been applied to reveal details of discharge operation. [4][5][6][7][8][9][10][11] In microdischarges excited by nanosecond pulses, transient electron dynamics takes place on a nano-or subnanosecond time scale. In combination with the small discharge dimensions, this makes numerical and experimental investigations particularly challenging.…”

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confidence: 99%

Kinetic simulation of a nanosecond-pulsed hydrogen microdischarge

Schulze

Muller

Czarnetzki

2011

Applied Physics Letters

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The electron dynamics in a nanosecond-pulsed microdischarge in high pressure hydrogen gas is investigated space and time resolved by particle-in-cell simulations. The discharge is driven by a 10 ns voltage pulse with a peak of 1.3 kV followed by an approximately constant voltage of 300 V during 150 ns. The time resolved current, electric field, electron density, and spatio-temporal excitation rates are compared to experimental and modeling results under identical discharge conditions. Via this synergistic approach, the development of the discharge and the different phases of distinct electron dynamics are identified and understood.

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Rapid formation of electric field profiles in repetitively pulsed high-voltage high-pressure nanosecond discharges

Cited by 66 publications

References 17 publications

Dynamics of Near-Atmospheric-Pressure Hydrogen Plasmas Driven by Pulsed High Voltages

Dynamics of Near-Atmospheric-Pressure Hydrogen Plasmas Driven by Pulsed High Voltages

Ignition of a nanosecond-pulsed near atmospheric pressure discharge in a narrow gap

Kinetic simulation of a nanosecond-pulsed hydrogen microdischarge

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