AVS 65th International Symposium & Exhibition | |
Plasma Science and Technology Division | Tuesday Sessions |
Session PS+PB+SE-TuA |
Session: | Atmospheric Pressure Plasmas |
Presenter: | Scott Walton, U.S. Naval Research Laboratory |
Authors: | S.G. Walton, U.S. Naval Research Laboratory J. Tomko, University of Virginia B.M. Foley, University of Virginia D.R. Boris, U.S. Naval Research Laboratory M.J. Johnson, National Research Council Tz.B. Petrova, U.S. Naval Research Laboratory A. Giri, University of Virginia P.E. Hopkins, University of Virginia |
Correspondent: | Click to Email |
The energy flux to a surface during plasma exposure and the associated surface heating are of long standing interest since both contribute to the physicochemical changes during plasma-based materials processing. A unique feature of plasmas compared to other methods of materials synthesis and processing is that the energy flux is delivered and absorbed at or very near the surface over short time scales, and thus requires fast, surface-sensitive techniques to fully appreciate the dynamics of the plasma-surface interface. To achieve this, we employ pump-probe Time-Domain Thermoreflectance (TDTR) to measure electron and phonon excitation and energy transport dynamics in thin metal films during exposure to an atmospheric pressure plasma jet. The results show the energy delivered by the plasma jet causes a localized thermal spike that is dissipated radially from the point of contact. More specifically, energy delivered via the flux of particles and photons causes the kinetic energy of the electrons within the material to increase over an area commensurate with the plasma jet radius. That energy is then dissipated through electron-electron collisions and electron-phonon interactions as the electrons propagate radially from the point of contact. These results, in conjunction with voltage and current measurements, will be discussed in an effort to develop a first order understanding of energy transfer and relevant kinetics during plasma jet–surface interactions. This work is partially supported by the Naval Research Laboratory base program.