Title :
Robust, stable, and accurate boundary movement for physical etching and deposition simulation
Author :
Hsiau, Ze-Kai ; Kan, Edwin C. ; McVittie, James P. ; Dutton, Robert W.
Author_Institution :
Center for Integrated Syst., Stanford Univ., CA, USA
fDate :
9/1/1997 12:00:00 AM
Abstract :
The increasing complexity of VLSI device interconnect features and fabrication technologies encountered by semiconductor etching and deposition simulation necessitates improvements in the robustness, numerical stability, and physical accuracy of the boundary movement method. The volume-mesh-based level set method, integrated with the physical models in SPEEDIE, demonstrates accuracy and robustness for simulations on a wide range of etching/deposition processes. The surface profile is reconstructed from the well-behaved level set function without rule-based algorithms. Adaptive gridding is used to accelerate the computation. The algorithm can be easily extended from two-dimensional (2-D) to three-dimensional (3-D), and applied to model microstructures consisting of multiple materials. Efficiency benchmarks show that this boundary movement method is practical in 2-D, and competitive for larger scale or 3-D modeling applications
Keywords :
VLSI; chemical vapour deposition; circuit analysis computing; digital simulation; etching; integrated circuit interconnections; mesh generation; semiconductor process modelling; 3D modeling applications; SPEEDIE; VLSI device interconnect features; adaptive gridding; boundary movement; deposition simulation; etching simulation; numerical stability; robustness; surface profile; volume-mesh-based level set method; Acceleration; Computational modeling; Etching; Fabrication; Level set; Numerical stability; Robust stability; Robustness; Surface reconstruction; Very large scale integration;
Journal_Title :
Electron Devices, IEEE Transactions on
