Title :
Plasma-etching profile model for SiO2 contact holes
Author :
Liu, Chunli ; Abraham-Shrauner, Barbara
Author_Institution :
Dept. of Electr. Eng., Washington Univ., St. Louis, MO, USA
fDate :
8/1/2002 12:00:00 AM
Abstract :
A theoretical plasma-etching model for contact holes (vias) is presented. The significant feature of this model is that the etch and deposition rates are given by analytical equations. The etch-profile simulations for the contact holes are computed from the trajectory equations of the surface-evolution equation by using a computer package of MATLAB. The ion and neutral etch rates are proportional to the energy and particle fluxes, respectively. A new approximate analytic expression for the ion-energy flux is reported for contact holes; the neutral flux expressions were found previously. The scanning-electron microscopy micrographs of SiO2 contact holes etched in a gas mixture of CF4/CHF3/Ar in a magnetically enhanced reactive ion etching reactor are fitted well using the developed model.
Keywords :
digital simulation; integrated circuit manufacture; scanning electron microscopy; semiconductor process modelling; silicon compounds; sputter etching; surface topography; MATLAB; MERIE; SiO2; SiO2 contact holes; analytic expression; analytical equations; characteristic equations; computer package; deposition rates; device area; electronics manufacturing; energy fluxes; etch rates; etch-profile simulations; etching; integrated circuits; ion etch rates; ion-energy flux; magnetically enhanced reactive ion etching reactor; neutral etch rates; particle fluxes; plasma-based surface processes; plasma-etching profile model; scanning-electron microscopy micrographs; semiconductor electronics devices; surface-evolution equation; tetrafluoromethane/trifluoromethane/Ar gas mixture; thermal stresses; trajectory equations; vias; Computational modeling; Computer simulation; Equations; Etching; MATLAB; Magnetic force microscopy; Mathematical model; Packaging; Plasma applications; Plasma simulation;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2002.804166
