Title :
RF models for plasma-surface interactions: Sheath boundary conditions with dielectrics
Author :
Jenkins, Thomas G. ; Smithe, David N.
Author_Institution :
Tech-X Corp., Boulder, CO, USA
Abstract :
Computational models for DC and oscillatory (RF-driven) sheath potentials, arising at metal or dielectric-coated surfaces in contact with plasma, are developed from first principles using particle-in-cell modeling in the VSim FDTD code. These results are used to formulate lumped-element boundary conditions1, applicable in both fluid2 and particle VSim modeling scenarios, wherein sub-grid models for sheaths or dielectric-modified sheaths retain self-consistency in modeling salient physical properties (e.g. sheath-modified particle and heat fluxes) at material surfaces. In this manner, sheath potentials, EEDF evolution, and sputtering physics associated with sheath formation can be included in macroscopic simulations which need not resolve the spatial scales of the sheath explicitly.
Keywords :
ab initio calculations; coatings; plasma materials processing; plasma oscillations; plasma sheaths; plasma simulation; plasma-wall interactions; sputtering; DC sheath potentials; EEDF evolution; RF model; VSim FDTD code; computational model; dielectric-coated surface; dielectric-modified sheath; first principles calculation; heat flux; lumped-element boundary condition; material surface; metal-coated surface; oscillatory sheath potentials; particle-in-cell model; physical properties; plasma-surface interaction; sheath boundary condition; sheath-modified particle; sputtering physics; subgrid model; Antennas; Computational modeling; Dielectrics; Heating; Plasmas; Radio frequency; Time-domain analysis;
Conference_Titel :
Plasma Sciences (ICOPS) held with 2014 IEEE International Conference on High-Power Particle Beams (BEAMS), 2014 IEEE 41st International Conference on
Conference_Location :
Washington, DC
Print_ISBN :
978-1-4799-2711-1
DOI :
10.1109/PLASMA.2014.7012561
