Simulation and analysis of coupled surface and grain boundary motion

At the microscopic level, many materials are made of smaller and randomly oriented grains. These grains are separated by grain boundaries which tend to decrease the electrical and thermal conductivity of the material. The motion of grain boundaries is an important phenomenon controlling the grain gr...

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Main Author: Pan, Zhenguo
Language:English
Published: University of British Columbia 2008
Subjects:
Online Access:http://hdl.handle.net/2429/2733
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spelling ndltd-LACETR-oai-collectionscanada.gc.ca-BVAU.2429-27332014-03-26T03:35:22Z Simulation and analysis of coupled surface and grain boundary motion Pan, Zhenguo Numerical simulation Grain boundary motion Surface diffusion Linear stability At the microscopic level, many materials are made of smaller and randomly oriented grains. These grains are separated by grain boundaries which tend to decrease the electrical and thermal conductivity of the material. The motion of grain boundaries is an important phenomenon controlling the grain growth in materials processing and synthesis. Mathematical modeling and simulation is a powerful tool for studying the motion of grain boundaries. The research reported in this thesis is focused on the numerical simulation and analysis of a coupled surface and grain boundary motion which models the evolution of grain boundary and the diffusion of the free surface during the process of grain growth. The “quarter loop” geometry provides a convenient model for the study of this coupled motion. Two types of normal curve velocities are involved in this model: motion by mean curvature and motion by surface diffusion. They are coupled together at a triple junction. A front tracking method is used to simulate the migration. To describe the problem, different formulations are presented and discussed. A new formulation that comprises partial differential equations and algebraic equations is proposed. It preserves arc length parametrization up to scaling and exhibits good numerical performance. This formulation is shown to be well-posed in a reduced, linear setting. Numerical simulations are implemented and compared for all formulations. The new formulation is also applied to some other related problems. We investigate numerically the linear stability of the travelling wave solutions for the quarter loop problem and a simple grain boundary motion problem for both curves in two dimensions and surfaces in three dimensions. The numerical results give evidence that they are convectively stable. A class of high order three-phase boundary motion problems are also studied. We consider a region where three phase boundaries meet at a triple junction and evolve with specified normal velocities. A system of partial differential algebraic equations (PDAE) is proposed to describe this class of problems by extending the discussion for the coupled surface and grain boundary motion. The linear well-posedness of the system is analyzed and numerical simulations are performed. 2008-10-30T19:42:22Z 2008-10-30T19:42:22Z 2008 2008-10-30T19:42:22Z 2009-05 Electronic Thesis or Dissertation http://hdl.handle.net/2429/2733 eng University of British Columbia
collection NDLTD
language English
sources NDLTD
topic Numerical simulation
Grain boundary motion
Surface diffusion
Linear stability
spellingShingle Numerical simulation
Grain boundary motion
Surface diffusion
Linear stability
Pan, Zhenguo
Simulation and analysis of coupled surface and grain boundary motion
description At the microscopic level, many materials are made of smaller and randomly oriented grains. These grains are separated by grain boundaries which tend to decrease the electrical and thermal conductivity of the material. The motion of grain boundaries is an important phenomenon controlling the grain growth in materials processing and synthesis. Mathematical modeling and simulation is a powerful tool for studying the motion of grain boundaries. The research reported in this thesis is focused on the numerical simulation and analysis of a coupled surface and grain boundary motion which models the evolution of grain boundary and the diffusion of the free surface during the process of grain growth. The “quarter loop” geometry provides a convenient model for the study of this coupled motion. Two types of normal curve velocities are involved in this model: motion by mean curvature and motion by surface diffusion. They are coupled together at a triple junction. A front tracking method is used to simulate the migration. To describe the problem, different formulations are presented and discussed. A new formulation that comprises partial differential equations and algebraic equations is proposed. It preserves arc length parametrization up to scaling and exhibits good numerical performance. This formulation is shown to be well-posed in a reduced, linear setting. Numerical simulations are implemented and compared for all formulations. The new formulation is also applied to some other related problems. We investigate numerically the linear stability of the travelling wave solutions for the quarter loop problem and a simple grain boundary motion problem for both curves in two dimensions and surfaces in three dimensions. The numerical results give evidence that they are convectively stable. A class of high order three-phase boundary motion problems are also studied. We consider a region where three phase boundaries meet at a triple junction and evolve with specified normal velocities. A system of partial differential algebraic equations (PDAE) is proposed to describe this class of problems by extending the discussion for the coupled surface and grain boundary motion. The linear well-posedness of the system is analyzed and numerical simulations are performed.
author Pan, Zhenguo
author_facet Pan, Zhenguo
author_sort Pan, Zhenguo
title Simulation and analysis of coupled surface and grain boundary motion
title_short Simulation and analysis of coupled surface and grain boundary motion
title_full Simulation and analysis of coupled surface and grain boundary motion
title_fullStr Simulation and analysis of coupled surface and grain boundary motion
title_full_unstemmed Simulation and analysis of coupled surface and grain boundary motion
title_sort simulation and analysis of coupled surface and grain boundary motion
publisher University of British Columbia
publishDate 2008
url http://hdl.handle.net/2429/2733
work_keys_str_mv AT panzhenguo simulationandanalysisofcoupledsurfaceandgrainboundarymotion
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