Abstract
In the present work, lattice Boltzmann models are proposed for the computer simulation of normal grain growth in two-dimensional systems with/without immobile dispersed second-phase particles and involving the temperature gradient effect. These models are demonstrated theoretically to be equivalent to the phase field models based on the multiscale expansion. Simulation results of several representative examples show that the proposed models can effectively and accurately simulate the grain growth in various single- and two-phase systems. It is found that the grain growth in single-phase polycrystalline materials follows the power-law kinetics and the immobile second-phase particles can inhibit the grain growth in two-phase systems. It is further demonstrated that the grain growth can be tuned by the second-phase particles and the introduction of temperature gradient is also an effective way for the fabrication of polycrystalline materials with grained gradient microstructures. The proposed models are useful for the numerical design of the microstructure of materials and provide effective tools to guide the experiments. Moreover, these models can be easily extended to simulate two- and three-dimensional grain growth with considering the mobile second-phase particles, transient heat transfer, melt convection, etc.
Highlights
Grain growth is a well-known process in the manufacture of materials through which various microstructures can be formed, which is closely related to the mechanical properties of materials
Lattice Boltzmann models are proposed for the computer simulation of normal grain growth in two-dimensional systems with/without immobile dispersed second-phase particles and involving the temperature gradient effect
SUMMARY Lattice Boltzmann models have been developed in this work to model the normal grain growth in two-dimensional systems with and without immobile dispersed second-phase particles and under prescribed temperature gradients
Summary
Grain growth is a well-known process in the manufacture of materials through which various microstructures can be formed, which is closely related to the mechanical properties of materials. We will focus on the developments and applications of lattice Boltzmann models for simulating the curvature-driven grain growth with and without immobile dispersed secondphase particles and under a specified temperature gradient. These models can be extended to model the grain growth behavior in single- and multi-phase systems involving the transient heat transfer and melt convection, such as the structures fabricated by using the selective laser melting technique, selective laser sintering technique, and so on.
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