Inception of snapover and gas induced glow discharges
Autor: | Galofaro, J. T., Vayner, B. V., Degroot, W. A., Ferguson, D. C., Thomson, C. D., JR Dennison, Davies, R. E. |
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Přispěvatelé: | NASA Center for Aerospace Information |
Předmět: |
spectroscopy
glow discharges earth orbital environments plasma physics low earth orbits Physics time constant gas discharges Condensed Matter Physics argon plasma dielectrics xenon anodic coatings secondary emission statistical analysis electric potential outgassing vacuum chambers luminescence Plasma and Beam Physics |
Zdroj: | Scopus-Elsevier Conference Proceedings All Physics Faculty Publications |
Popis: | Ground based experiments of the snapover phenomenon were conducted in the large vertical simulation chamber at the Glenn Research Center (GRC) Plasma Interaction Facility (PIF). Two Penning sources provided both argon and xenon plasmas for the experiments. The sources were used to simulate a variety of ionospheric densities pertaining to a spacecraft in a Low Earth Orbital (LEO) environment. Secondary electron emission is believed responsible for dielectric surface charging, and all subsequent snapover phenomena observed. Voltage sweeps of conductor potentials versus collected current were recorded in order to examine the specific charging history of each sample. The average time constant for sample charging was estimated between 25 and 50 seconds for all samples. It appears that current drops off by approximately a factor of 3 over the charging time of the sample. All samples charged in the forward and reverse bias directions, demonstrated hysteresis. Current jumps were only observed in the forward or positive swept voltage direction. There is large dispersion in tile critical snapover potential when repeating sweeps on any one sample. The current ratio for the first snapover region jumps between 2 and 4.6 times, with a standard deviation less than 1.6. Two of the samples showed even larger current ratios. It is believed the second large snapover region is due to sample outgassing. Under certain preset conditions, namely at the higher neutral gas background pressures, a perceptible blue-green glow was observed around the conductor. The glow is believed to be a result of secondary electrons undergoing collisions with an expelled tenuous cloud of gas, that is outgassed from the sample. Spectroscopic measurements of the glow discharge were made in an attempt to identify specific lines contributing to the observed glow. |
Databáze: | OpenAIRE |
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