Title :
Simulation of SiO2 charging
Author :
Vicario, E. ; Renoud, R. ; Rosenberg, N.
Author_Institution :
Dept. de Phys. des Mater., Univ. Claude Bernard, Villeurbanne, France
Abstract :
The single scattering technique in the Monte Carlo simulating method is used: the electron trajectory is divided in several straight segments; the length of each segment is a random fraction of the elastic mean free path, an elastic diffusion is considered at the end of each segment. The screened Rutherford cross section accounts for the elastic interaction. Inelastic interaction is introduced: a) either via the inelastic mean free path and the energy loss cross section concepts; b) or by the Bethe-Wittry continuous slowing-down model. The energy loss is assumed to be devoted to secondary electron creation; the secondary electron energy is deduced from the Streitwolf formula. The intensity of the total secondary electron yield is fitted to the experimental results by adjusting the value of two parameters which respectively describe the cascade multiplication rate and the mean absorption coefficient
Keywords :
surface charging; Bethe-Wittry continuous slowing-down model; Monte Carlo simulation; SiO2; SiO2 charging; Streitwolf formula; absorption coefficient; cascade multiplication; elastic diffusion; elastic mean free path; electron trajectory; energy loss cross section; inelastic mean free path; screened Rutherford cross section; secondary electron yield; single scattering; Absorption; Backscatter; Crystallography; Displays; Electrons; Energy loss; Exponential distribution; Light scattering; Mirrors; Spontaneous emission;
Conference_Titel :
Electrical Insulation and Dielectric Phenomena, 1994., IEEE 1994 Annual Report., Conference on
Conference_Location :
Arlington, TX
Print_ISBN :
0-7803-1950-8
DOI :
10.1109/CEIDP.1994.591747
