Gas flows in plasma etching reactors for semiconductor fabrication became a chief consideration in designing second-generation reactors with higher etching rates. An axisymmetrical model based on the direct simulation Monte Carlo method has been developed for analyzing rarefied gas flows in a vacuum chamber with the conditions of downstream pressure and gas flow rate. By using this simulator, rarefied gas flows with radicals and etch-products were calculated for microwave-plasma etching reactors. The results showed that the flow patterns in the plasma chamber strongly depend on the Knudsen number and the gas-supply structure. The ventilation of the etch-products in the plasma chamber was found to be improved both for higher Knudsen numbers and for gas-supply structures of the downward-flow type, as compared with those of the radial-flow or upward-flow types.

Issue Section:
Additional Technical Papers
Keywords:
semiconductor device manufacture, etching, plasma applications, rarefied fluid dynamics, Monte Carlo methods
Topics:
Etching, Flow (Dynamics), Gas flow, Knudsen number, Plasma etching, Pressure, Ventilation, Plasmas (Ionized gases), Rarefied fluid dynamics, Simulation, Microwaves
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