Experimental investigation of atmospheric pressure nonequilibrium plasma chemistry

Atmospheric pressure plasmas are frequently considered to be in local thermodynamic equilibrium due to the high frequency of collisional processes which drive the plasma state toward a Maxwell-Boltzmann equilibrium. However, various forms of thermodynamic, ionizational, and chemical nonequilibrium h...

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Bibliographic Details
Published in:IEEE transactions on plasma science 1997-10, Vol.25 (5), p.1042-1051
Main Authors: Kruger, C.H., Owano, T.G., Laux, C.O.
Format: Article
Language:English
Subjects:
Atmosphere
Atmospheric-pressure plasmas
Chemical processes
Chemistry
Experiments
Frequency
Kinetic theory
Kinetics
Laboratories
Manufacturing processes
Plasma
Plasma applications
Plasma chemistry
Plasma materials processing
Thermodynamics
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Summary:Atmospheric pressure plasmas are frequently considered to be in local thermodynamic equilibrium due to the high frequency of collisional processes which drive the plasma state toward a Maxwell-Boltzmann equilibrium. However, various forms of thermodynamic, ionizational, and chemical nonequilibrium have been demonstrated and investigated in atmospheric pressure plasma environments over the last several years, and the nonequilibrium behaviour of such systems can be quite significant. The investigation, understanding, and exploitation of atmospheric pressure nonequilibrium plasma chemistry is necessary to the further expansion of plasma-based systems into mainstream manufacturing and processing applications. Several experimental programs to investigate the fundamental processes of atmospheric pressure nonequilibrium plasma chemistry and the application of this nonequilibrium to various chemical systems have been undertaken in our laboratories, The results of these investigations have shed light on the kinetics behind various forms of atmospheric pressure nonequilibrium chemistry, and have provided insights into the beneficial control of nonequilibrium plasma chemistry for processing applications.
ISSN:0093-3813
1939-9375
DOI:10.1109/27.649624