Title :
Direct simulation Monte Carlo analysis of flows and etch rate in an inductively coupled plasma reactor
Author :
Nanbu, Kenichi ; Morimoto, Tamotsu ; Suetani, Masaharu
Author_Institution :
Inst. of Fluid Sci., Tohoku Univ., Sendai, Japan
fDate :
10/1/1999 12:00:00 AM
Abstract :
The direct simulation Monte Carlo (DSMC) method was employed to predict the etch rate distribution on Si wafer. The etchant is assumed to be Cl. The production rate of Cl due to electron impact was obtained separately by preprocessing an inductively coupled chlorine plasma by use of the particle-in-cell/Monte Carlo method. Under the condition of constant total pressure, the etch rate increases with the mass flow rate of source gas Cl2. The density of the etch product SiCl2 rapidly decreases with increasing the flow rate. The density of the etchant hardly depends on the flow rate. The recombination 2Cl→Cl2 on the inner walls of etching apparatus has a large effect on the etch rate; recombination probability of 0.1 results in 50% reduction of the etch rate. The etch rate distribution becomes more uniform when the reaction probability at the wafer surface is reduced
Keywords :
Monte Carlo methods; elemental semiconductors; plasma flow; plasma materials processing; plasma simulation; silicon; sputter etching; Cl; Cl etchant; Cl production rate; Si; Si wafer; SiCl2 etch product; constant total pressure; density; direct simulation Monte Carlo analysis; electron impact; etch rate; etch rate distribution; flow rate; flows; inductively coupled plasma reactor; mass flow rate; particle-in-cell/Monte Carlo method; reaction probability; recombination probability; semiconductor; Analytical models; Electrons; Etching; Monte Carlo methods; Particle production; Plasma applications; Plasma density; Plasma simulation; Plasma sources; Predictive models;
Journal_Title :
Plasma Science, IEEE Transactions on
