2006
DOI: 10.1143/jjap.45.8157
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A Model Analysis of Feature Profile Evolution and Microscopic Uniformity during Polysilicon Gate Etching in Cl2/O2 Plasmas

Abstract: A phenomenological model has been developed to simulate the feature profile evolution of polycrystalline silicon (poly-Si) gate etching in Cl 2 /O 2 plasmas. The model takes into account the deposition of etch products, surface oxidation, and the forward reflection of energetic ions on feature sidewalls. To describe the formation of multilayer SiCl x or SiCl x O y on feature surfaces during etching, the substrates consist of a number of small cells or lattices of atomic size in the computational domain; this m… Show more

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Cited by 33 publications
(35 citation statements)
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“…The ASCeM-3D methodology has been described in part in our previous papers, 46,47 together with the surface chemistry and kinetics concerned, which is basically an extension of the ASCeM-2D. [40][41][42][43][44][45] In more detail, the simulation domain is a square W ¼ 50 nm on a side with a depth of 630 nm, consisting of a number of small cubic cells of atomic size L ¼ q Si À1/3 ¼ 2.7 Å (185 Â 185 Â 2333 % 8 Â 10 7 cells in total), where q Si ¼ 5.0 Â 10 22 cm À3 is the atomic density of Si substrates. The substrates initially occupy a lower 620-nm-deep layer therein (or the substrate surfaces are initially flat, being located 10 nm downward from the top of the domain).…”
Section: Numerical Analysismentioning
confidence: 99%
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“…The ASCeM-3D methodology has been described in part in our previous papers, 46,47 together with the surface chemistry and kinetics concerned, which is basically an extension of the ASCeM-2D. [40][41][42][43][44][45] In more detail, the simulation domain is a square W ¼ 50 nm on a side with a depth of 630 nm, consisting of a number of small cubic cells of atomic size L ¼ q Si À1/3 ¼ 2.7 Å (185 Â 185 Â 2333 % 8 Â 10 7 cells in total), where q Si ¼ 5.0 Â 10 22 cm À3 is the atomic density of Si substrates. The substrates initially occupy a lower 620-nm-deep layer therein (or the substrate surfaces are initially flat, being located 10 nm downward from the top of the domain).…”
Section: Numerical Analysismentioning
confidence: 99%
“…Moreover, the ASCeM-3D takes into account two-body elastic collisions between energetic ions and substrate Si atoms, 41,47 to analyze the ion reflection or scattering from feature surfaces on incidence into vacuum and the ion penetration into substrates. 59,60 The analysis is also based on the 3D Monte Carlo calculation of ion trajectories according to the momentum and energy conservation through successive collisions with substrate Si atoms; then, the ions reflected from the surface into vacuum move further toward another surfaces of the feature or go out of the simulation domain.…”
Section: Surface Chemistry and Kineticsmentioning
confidence: 99%
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“…The taper angle is larger or the deposition is more significant for wider space features, owing to the geometrical shadowing for incoming etch byproducts ͑or surface inhibitors͒, which has been observed experimentally in Si etching with Cl 2 , 40,45,46 Cl 2 / O 2 , 40,45 HBr, 46 and Cl 2 / HBr/ O 2 47,48 plasmas. This is in contrast to the sidewall tapering caused by redeposition of etch products desorbed from feature surfaces, which is more significant for narrower features ͑see Fig.…”
Section: Without Surface Oxidation "⌫ O 0 =0…mentioning
confidence: 95%