K.H. Schoenbach scite author profile

A fluid model has been developed and used to help clarify the physical mechanisms occurring in microhollow cathode discharges (MHCD). Calculated current-voltage (I-V) characteristics and gas temperatures in xenon at 100 Torr are presented. Consistent with previous experimental results in similar conditions, we find a voltage maximum in the I-V characteristic. We show that this structure reflects a transition between a low-current, abnormal discharge localized inside the cylindrical hollow cathode to a higher-current, normal glow discharge sustained by electron emission from the outer surface of the cathode. This transition, due to the geometry of the device, is a factor contributing to the well-known stability of MHCDs.

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Paschen’s law for a hollow cathode discharge

Eichhorn

Schoenbach

Tessnow

1993

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An expression for the breakdown voltage of a one-dimensional hollow cathode discharge has been derived. The breakdown condition which corresponds to Paschen’s law contains, in addition to the first Townsend coefficient, and the secondary electron emission coefficient two parameters which characterize the reflecting action of the electric field and the lifetime of the electrons in the discharge. The breakdown voltage for a hollow cathode discharge in helium was calculated and compared to that of a glow discharge operating under similar conditions.

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On the road to compact pulsed power: adventures in materials, electromagnetic modeling, and thermal management

Schamiloglu

Schoenbach²,

Vidmar³

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Parallel operation of microhollow cathode discharges

Shi

Stark

Schoenbach

1999

IEEE Trans. Plasma Sci.

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Gas temperature measurements in high pressure glow discharges in air

Block

Toedter

Schoenbach

1999

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The temporal development of hollow cathode discharges

Ngo

Schoenbach

Gerdin

et al. 1990

IEEE Trans. Plasma Sci.

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Oxygen enhances lethal effect of high‐intensity, ultrashort electrical pulses

Walker¹,

Pakhomova

Kolb

et al. 2006

Bioelectromagnetics

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The study explored the effect of ambient oxygen on mammalian cell survival after exposure to 10 ns duration, high voltage electrical pulses (nsEP, 80-90 or 120-130 kV/cm; 200-400 pulses per exposure). Cell samples were equilibrated with pure nitrogen, atmospheric air, or pure oxygen prior to the nsEP treatment and were returned to the incubator (air + 5% CO2) shortly after the exposure. The experiments established that survival of hypoxic Jurkat and U937 cells exceeded that of air-equilibrated controls about twofold (P < .01). Conversely, saturation of the medium with oxygen prior to exposure decreased Jurkat cell survival about 1.5 times, P < .01. Attenuation of the cytotoxic effect under hypoxic conditions resembled a well-known effect of oxygen on cell killing by sparsely ionizing radiations and may be indicative of the similarity of underlying cell damage mechanisms.

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Biofouling prevention with pulsed electric fields

Schoenbach

Alden

Fox³

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K.H. Schoenbach

Predicted properties of microhollow cathode discharges in xenon

Paschen’s law for a hollow cathode discharge

On the road to compact pulsed power: adventures in materials, electromagnetic modeling, and thermal management

Parallel operation of microhollow cathode discharges

Gas temperature measurements in high pressure glow discharges in air

The temporal development of hollow cathode discharges

Oxygen enhances lethal effect of high‐intensity, ultrashort electrical pulses

Biofouling prevention with pulsed electric fields

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