Title :
Numerical modeling of silicon film deposition in very-high-frequency plasma reactor
Author :
Satake, Koji ; Kobayashi, Yasuyuki ; Morita, Shoji
Author_Institution :
Adv. Technol. Res. Center, Mitsubishi Heavy Industries Ltd., Kanazawa, Japan
Abstract :
We present a numerical modeling of plasma-enhanced chemical vapor deposition (PECVD) of silicon film from SiH4 and H2 gas mixtures in very-high-frequency (VHF) plasma reactor. The model is composed by electron impact, gas-phase, and surface reactions in a well-mixed reactor model. A set of plasma parameters such as electron density, electron temperature and electron impact reaction rates is determined separately by nonequilibrium plasma model and used as inputs for well-mixed reactor models. The gas-phase reactions include electron impact and neutral-neutral reactions. Some of unknown rates of surface reactions are determined using quantum chemical calculations and transition state theory. In well-mixed reactor models, concentrations of each chemical species are calculated in a steady state condition using mass conservation equation uniformed through the reactor. Numerical results of growth rate as a function of plasma reactor operating parameters show good agreement with experimental ones. Finally optimal operating parameters are investigated using our model combined with design of experiments and optimization techniques.
Keywords :
elemental semiconductors; plasma CVD coatings; semiconductor growth; semiconductor process modelling; semiconductor thin films; silicon; surface chemistry; Si; Si film deposition; electron density; electron impact; electron impact reaction rates; electron temperature; film deposition in very-high-frequency plasma reactor; gas phase reactions; nonequilibrium plasma model; numerical modeling; plasma-enhanced chemical vapor deposition; quantum chemical calculations; surface reactions; transition state theory; well-mixed reactor model; Chemical vapor deposition; Electrons; Inductors; Numerical models; Plasma chemistry; Plasma density; Plasma temperature; Quantum mechanics; Semiconductor films; Silicon;
Conference_Titel :
Simulation of Semiconductor Processes and Devices, 2002. SISPAD 2002. International Conference on
Print_ISBN :
4-89114-027-5
DOI :
10.1109/SISPAD.2002.1034535
