The production mechanisms of OH radicals in a pulsed direct current plasma jet


Autoria(s): Liu, X.Y.; Pei, X.K.; Ostrikov, K.; Lu, X.P.; Liu, D.W.
Data(s)

2014

Resumo

The production mechanism of OH radicals in a pulsed DC plasma jet is studied by a two-dimensional (2-D) plasma jet model and a one-dimensional (1-D) discharge model. For the plasma jet in the open air, electron-impact dissociation of H2O, electron neutralization of H2O+, as well as dissociation of H2O by O(1D) are found to be the main reactions to generate the OH species. The contribution of the dissociation of H2O by electron is more than the others. The additions of N2, O2, air, and H2O into the working gas increase the OH density outside the tube slightly, which is attributed to more electrons produced by Penning ionization. On the other hand, the additions of O2 and H2O into the working gas increase the OH density inside the tube substantially, which is attributed to the increased O (1D) and H2O concentration, respectively. The gas flow will transport high density OH out of the tube during pulse off period. It is also shown that the plasma chemistry and reactivity can be effectively controlled by the pulse numbers. These results are supported by the laser induced fluorescence measurements and are relevant to several applications of atmospheric-pressure plasmas in health care, medicine, and materials processing.

Formato

application/pdf

Identificador

http://eprints.qut.edu.au/88879/

Publicador

American Institute of Physics

Relação

http://eprints.qut.edu.au/88879/2/88879.pdf

DOI:10.1063/1.4895496

Liu, X.Y., Pei, X.K., Ostrikov, K., Lu, X.P., & Liu, D.W. (2014) The production mechanisms of OH radicals in a pulsed direct current plasma jet. Physics of Plasmas, 21(9), 093513-1.

FUNDAMENTAL RESEARCH/AEET2014ZZ007

SRF/

Direitos

Copyright 2014 American Institute of Physics

Fonte

School of Chemistry, Physics & Mechanical Engineering; Science & Engineering Faculty

Tipo

Journal Article