J. R. Bayless scite author profile

Non-thermal plasma processing methods have been shown to be effective for treating dilute concentrations of pollutants in large-volume atmospheric-pressure air streams. This paper presents results from basic experimental and theoretical studies aimed at identifying the main reactions responsible for the decomposition of four representative compounds: carbon tetrachloride, methylene chloride, trichloroethylene and methanol. Each of these compounds is shown to be decomposed by a different plasma species: electrons, nitrogen atoms, oxygen radicals and positive ions, respectively. By understanding what plasma species is responsible for the decomposition of a pollutant molecule, it is possible to establish the electrical power requirements of the plasma reactor and help identify the initial reactions that lead to the subsequent process chemistry. These studies are essential for predicting the scaling of the process to commercial size units.

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Neuropsychological Characteristics of Patients in a Hospital-Based Eating Disorder Program

Bayless¹,

Kanz²,

Moser³

et al. 2002

Ann. of Clinical Psychiatry

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Electron beam and pulsed corona processing of volatile organic compounds in gas streams

Penetrante¹,

Hsiao²,

Bardsley³

et al. 1996

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Electron beam and pulsed corona processing of carbon tetrachloride in atmospheric pressure gas streams

et al. 1995

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Electron-impact dissociation of molecular nitrogen in atmospheric-pressure nonthermal plasma reactors

Penetrante

Hsiao

Merritt

et al. 1995

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This letter presents measurements of the specific energy consumption (eV per molecule) for electron-impact dissociation of N2 (e+N2→e+N+N) in a pulsed corona and an electron beam reactor. Measurements were done using 100 pm of NO in N2. In this mixture the removal of NO is dominated by the reduction reaction N+NO→N2+O. By measuring the specific energy consumption for reduction of NO, these experiments provide a good measure of the specific energy consumption for electron-impact dissociation of N2. The specific energy consumption using pulsed corona processing is 480 eV per dissociated N2 molecule. For electron beam processing, the specific energy consumption is 80 eV per dissociated N2 molecule.

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J. R. Bayless

Identification of mechanisms for decomposition of air pollutants by non-thermal plasma processing

Neuropsychological Characteristics of Patients in a Hospital-Based Eating Disorder Program

Electron beam and pulsed corona processing of volatile organic compounds in gas streams

Electron beam and pulsed corona processing of carbon tetrachloride in atmospheric pressure gas streams

Electron-impact dissociation of molecular nitrogen in atmospheric-pressure nonthermal plasma reactors

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