Type of Document Master's Thesis Author Behera, Rakesh Kumar Author's Email Address firstname.lastname@example.org URN etd-07092004-113612 Title Mesoscopic Simulation of Abnormal Grain Growth Degree Master of Science (M.S.) Department Mechanical Engineering Advisory Committee
Advisor Name Title Dorel Moldovan Committee Chair Aravamudhan Raman Committee Member Efstathios I. Meletis Committee Member Keywords
- monte carlo
- grain growth
Date of Defense 2004-07-08 Availability unrestricted AbstractGrain growth is the process that takes place during annealing of polycrystalline materials; its major feature is a systematic increase in grain size. Two different types of grain growth can be distinguished: the normal and abnormal grain growth. During normal grain growth, the microstructure exhibits a uniform increase in grain size with time and the grain size distribution follows the log-normal distribution with the grain sizes ranging from 0 - 2.2 times the average grain size (R). On the contrary, when the abnormal grain growth is the dominant mechanism, there are certain grains (abnormal grains) in the microstructure that grow much faster than the majority of the grains and in the end consume the fine-grained matrix around them. There has been a lot of work done in the field of abnormal grain growth, but the actual mechanism of abnormal grain formation and development from a uniform grain size distribution is not fully understood. In this study, various aspects of abnormal grain growth are investigated using a mesoscopic simulation approach.
Our investigation focuses on two possible venues that are, in general, considered as main sources promoting abnormal grain growth. The role of both the geometrical inhomogeneities (size effect) and grain boundary (GB) anisotropic properties are investigated. Simulations are done on various microstructures in which there are certain fraction of preexistent large grains (size greater than 2.2
), as well as on microstructures in which a given fraction of grains has different GB properties (mobility and energy). Our simulation results indicate that the presence of some large grains in the initial microstructure does not promote the abnormal grain growth. However, when certain grains in the microstructure have grain boundary energies below a certain threshold or mobilities above a certain threshold value relative to the rest of the grains, the microstructure may evolve by abnormal grain growth.
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