Synthesis of Hydrogen Peroxide Using Dielectric Barrier Discharge Associated with Fibrous Materials

A new synthesis pathway toward hydrogen peroxide has been investigated using non-thermal plasma. This work is aimed at studying the activation of oxygen/hydrogen mixtures by a cylindrical dielectric barrier discharge. An experimental device has been especially developed for this application, it main...

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Veröffentlicht in:Plasma chemistry and plasma processing 2010, Vol.30 (4), p.489-502
Hauptverfasser: Thevenet, F., Couble, J., Brandhorst, M., Dubois, J. L., Puzenat, E., Guillard, C., Bianchi, D.
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Sprache:eng
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Zusammenfassung:A new synthesis pathway toward hydrogen peroxide has been investigated using non-thermal plasma. This work is aimed at studying the activation of oxygen/hydrogen mixtures by a cylindrical dielectric barrier discharge. An experimental device has been especially developed for this application, it mainly differs from other cylindrical discharges in that the liquid ground electrode, and subsequently the reactor, can be regulated in temperature. The formation of hydrogen peroxide is reported (1) in a gas phase discharge and (2) in surface discharge. The gas phase discharge, characterized by an empty discharge gap, lead to a low activation of O 2 into O 2 /H 2 mixtures and poor selectivity toward H 2 O 2 . The modification of the discharge into a surface discharge, by introducing in the gap fibrous materials, considerably improves the efficiency of the process. The influence of the temperature on H 2 O 2 formation is discussed and correlated to the formation of a water layer on fibre surface. This layer appears to be a crucial point into H 2 O 2 plasma synthesis. The presence of TiO 2 on the fibre surface is reported as improving the stabilisation of hydrogen peroxide. The formation of a complex between H 2 O 2 and TiO 2 is suggested and discussed. The formation of H 2 O 2 in the gas phase or in the aqueous condensed phase is finally discussed. The investigation of the influence of the reactant gas composition and the presence or not of water, lead to the conclusion that (1) both H 2 and O 2 are required to achieve the synthesis reaction; (2) H 2 O 2 is formed in the gas phase and then solubilised and/or stabilised in the water layer. A global reaction pathway is finally proposed to summarize the synthesis reaction.
ISSN:0272-4324
1572-8986
DOI:10.1007/s11090-010-9234-7