M. Butcher scite author profile

An electrical breakdown model for liquids in response to a submicrosecond (∼100ns) voltage pulse is presented, and quantitative evaluations carried out. It is proposed that breakdown is initiated by field emission at the interface of pre-existing microbubbles. Impact ionization within the microbubble gas then contributes to plasma development, with cathode injection having a delayed and secondary role. Continuous field emission at the streamer tip contributes to filament growth and propagation. This model can adequately explain almost all of the experimentally observed features, including dendritic structures and fluctuations in the prebreakdown current. Two-dimensional, time-dependent simulations have been carried out based on a continuum model for water, though the results are quite general. Monte Carlo simulations provide the relevant transport parameters for our model. Our quantitative predictions match the available data quite well, including the breakdown delay times and observed optical emission.

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Conduction and breakdown mechanismsin transformer oil

Butcher

Neuber

Cevallos

et al. 2006

IEEE Trans. Plasma Sci.

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Electric current in dc surface flashover in vacuum

Neuber

Butcher

Hatfield

et al. 1999

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Dielectric surface flashover in vacuum is characterized by a three-phase development, as shown by current measurements covering the range from 10−4 to 100 A, assisted by x-ray emission measurements, high speed photography, and time-resolved spectroscopy. Further information is gained from a comparison of the flashover dynamics at 77 and 300 K. Phase one comprises a fast (several nanoseconds) buildup of a saturated secondary electron avalanche reaching current levels of 10 to 100 mA. Phase two is associated with a slow current amplification, with a duration on the order of 100 ns, reaching currents in the ampere level. The final phase three is characterized again by a fast (nanoseconds) current rise up to the impedance-limited current on the order of 100 A in this specific apparatus. The development during phase two and three is described by a zero-dimensional model, where electron-induced outgassing leads to a Townsend-like gas discharge above the surface. The feedback mechanism towards a self-sustained discharge is due to space charges leading to an enhanced field emission from the cathode. A priori unknown model parameters, such as field enhancement factors, outgassing rate, and the buildup of the gas density above the surface, are determined by fitting calculated results to experimental data.

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MBE lanthanum-based high-k gate dielectrics as candidates for SiO2 gate oxide replacement

Vellianitis

Αποστολόπουλος

Mavrou

et al. 2004

Materials Science and Engineering: B

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M. Butcher

The role of outgassing in surface flashover under vacuum

Microbubble-based model analysis of liquid breakdown initiation by a submicrosecond pulse

Conduction and breakdown mechanismsin transformer oil

Electric current in dc surface flashover in vacuum

MBE lanthanum-based high-k gate dielectrics as candidates for SiO2 gate oxide replacement

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