B. Haindl scite author profile

For wafer sizes in state-of-the-art semiconductor manufacturing ranging up to 300 mm, the uniformity of processes across the wafer becomes a very important issue. We present a fully three-dimensional model for the feature scale simulation of continuum transport and reaction determined high-pressure chemical vapor deposition processes suitable for the investigation of such nonuniformities. The newly developed three-dimensional approach combines topography simulation, meshing, and finite element method tools, and allows simulations over arbitrary geometries such as structures resulting from nonuniform underlying physical vapor deposition films. This enables the examination of film profile variations across the wafer for multistep processes consisting of low-and high-pressure parts such as Ti/TiN/W plugfills. Additionally, the model allows a very flexible formulation of the involved gas chemistry and surface reactions and can easily be extended to process chemistries including gas phase reactions of precursors as observed in deposition of silicon dioxide from tetraethylorthosilicate (TEOS). We show simulation examples for a tungsten deposition process, which is applied as last step in a Ti/TiN/W plug-fill. For filling of an L-shaped trench, we show the transition from transport to reaction limited process conditions.

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Investigation of a mesh criterion for three-dimensional finite element diffusion simulation

Fleischmann

Haindl²,

Kosik³

et al.

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Comparison of finite element and finite box discretization for three-dimensional diffusion modeling using AMIGOS

Haindl¹,

Kosik²,

Fleischmann³

et al.

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Linking three-dimensional topography simulation with high pressure CVD reaction kinetics

Pyka¹,

Fleischmann²,

Haindl³

et al.

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We present a three-dimensional model for the simulation of continuum transport and reaction determined high pressure CVD processes. Our approach allows simulations over arbitrary geometries such as structures resulting from nonuniform underlying PVD films. This enables the examination of film profile variations across the wafer for multi-step processes consisting of low and high pressure parts such as Ti/TiN/W plug-fills. Additionally the model allows a very flexible formulation of the involved chemistry and can easily be extended to arbitrary CVD processes including gas phase reactions of precursors as observed in the deposition of silicon dioxide from tetraethylorthosilicate (TEOS).

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B. Haindl

On the interplay between meshing and discretization in three-dimensional diffusion simulation

Three-dimensional simulation of HPCVD-linking continuum transport and reaction kinetics with topography simulation

Investigation of a mesh criterion for three-dimensional finite element diffusion simulation

Comparison of finite element and finite box discretization for three-dimensional diffusion modeling using AMIGOS

Linking three-dimensional topography simulation with high pressure CVD reaction kinetics

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