Analysis of particle engulfment during the growth of crystalline silicon

Yutao Tao; Andrew Yeckel; Jeffrey J Derby

doi:10.1016/j.jcrysgro.2015.12.037

Analysis of particle engulfment during the growth of crystalline silicon

Yutao Tao, Andrew Yeckel, Jeffrey J Derby

Chemical Engineering and Materials Science

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

To better understand the physical mechanisms responsible for foreign inclusions during the growth of crystalline silicon, steady-state and dynamic models are developed to simulate the engulfment of solid particles by solidification fronts. A Galerkin finite element method is developed to accurately represent forces and interfacial phenomena previously inaccessible by approaches using analytical approximations. The steady-state model is able to evaluate critical engulfment velocities, which are further validated using the dynamic model. When compared with experimental results for the SiC-Si system, our model predicts a more realistic scaling of critical velocity with particle size than that predicted by prior theories. Discrepancies between model predictions and experimental results for larger particles are posited to arise from dynamic effects, a topic worthy of future attention.

Original language	English (US)
Pages (from-to)	1-5
Number of pages	5
Journal	Journal of Crystal Growth
Volume	452
DOIs	https://doi.org/10.1016/j.jcrysgro.2015.12.037
State	Published - Oct 15 2016

Keywords

A1. Computer simulation
A1. Fluid flows
A1. Heat transfer
A2. Particle engulfment
B2. Multicrystalline silicon
B3. Solar cells

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title = "Analysis of particle engulfment during the growth of crystalline silicon",

abstract = "To better understand the physical mechanisms responsible for foreign inclusions during the growth of crystalline silicon, steady-state and dynamic models are developed to simulate the engulfment of solid particles by solidification fronts. A Galerkin finite element method is developed to accurately represent forces and interfacial phenomena previously inaccessible by approaches using analytical approximations. The steady-state model is able to evaluate critical engulfment velocities, which are further validated using the dynamic model. When compared with experimental results for the SiC-Si system, our model predicts a more realistic scaling of critical velocity with particle size than that predicted by prior theories. Discrepancies between model predictions and experimental results for larger particles are posited to arise from dynamic effects, a topic worthy of future attention.",

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AU - Yeckel, Andrew

AU - Derby, Jeffrey J

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N2 - To better understand the physical mechanisms responsible for foreign inclusions during the growth of crystalline silicon, steady-state and dynamic models are developed to simulate the engulfment of solid particles by solidification fronts. A Galerkin finite element method is developed to accurately represent forces and interfacial phenomena previously inaccessible by approaches using analytical approximations. The steady-state model is able to evaluate critical engulfment velocities, which are further validated using the dynamic model. When compared with experimental results for the SiC-Si system, our model predicts a more realistic scaling of critical velocity with particle size than that predicted by prior theories. Discrepancies between model predictions and experimental results for larger particles are posited to arise from dynamic effects, a topic worthy of future attention.

AB - To better understand the physical mechanisms responsible for foreign inclusions during the growth of crystalline silicon, steady-state and dynamic models are developed to simulate the engulfment of solid particles by solidification fronts. A Galerkin finite element method is developed to accurately represent forces and interfacial phenomena previously inaccessible by approaches using analytical approximations. The steady-state model is able to evaluate critical engulfment velocities, which are further validated using the dynamic model. When compared with experimental results for the SiC-Si system, our model predicts a more realistic scaling of critical velocity with particle size than that predicted by prior theories. Discrepancies between model predictions and experimental results for larger particles are posited to arise from dynamic effects, a topic worthy of future attention.

KW - A1. Computer simulation

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