Your search keyword '"anisotropic subgrain growth"' showing total 2 results

1. Large-Scale Multi-Phase-Field Simulation of 2D Subgrain Growth.

Author

Khajezade, Ali, Poole, Warren J., Greenwood, Michael, and Militzer, Matthias

Subjects

RECRYSTALLIZATION (Metallurgy), MICROSTRUCTURE

Abstract

The characteristics of subgrains in a deformed state after the high-temperature deformation of aluminum alloys control the subsequent recrystallization process and corresponding mechanical properties. In this study, systematic 2D phase-field simulations have been conducted to determine the role of deformed state parameters such as subgrain size and disorientation distributions on subgrain growth in an individual grain representing a single crystallographic orientation. The initial subgrain size and disorientation distributions have been varied by ±50%. To have a statistically relevant number of subgrains, large-scale simulations have been conducted using an in-house-developed phase-field code that takes advantage of distributed computing. The results of these simulations indicate that the growth of subgrains reaches a self-similar regime regardless of the initial subgrain structure. A narrower initial subgrain size distribution leads to faster growth rates, but it is the initial disorientation distribution that has a larger impact on the growth of subgrains. The results are discussed in terms of the evolution of the average diameter of subgrains and the average disorientation in the microstructure. [ABSTRACT FROM AUTHOR]

Published

2024

2. Large-Scale Multi-Phase-Field Simulation of 2D Subgrain Growth

Author

Ali Khajezade, Warren J. Poole, Michael Greenwood, and Matthias Militzer

Subjects

grain growth, phase-field modeling, anisotropic subgrain growth, aluminum alloys, subgrain size distribution, disorientation distribution, Mining engineering. Metallurgy, TN1-997

Abstract

The characteristics of subgrains in a deformed state after the high-temperature deformation of aluminum alloys control the subsequent recrystallization process and corresponding mechanical properties. In this study, systematic 2D phase-field simulations have been conducted to determine the role of deformed state parameters such as subgrain size and disorientation distributions on subgrain growth in an individual grain representing a single crystallographic orientation. The initial subgrain size and disorientation distributions have been varied by ±50%. To have a statistically relevant number of subgrains, large-scale simulations have been conducted using an in-house-developed phase-field code that takes advantage of distributed computing. The results of these simulations indicate that the growth of subgrains reaches a self-similar regime regardless of the initial subgrain structure. A narrower initial subgrain size distribution leads to faster growth rates, but it is the initial disorientation distribution that has a larger impact on the growth of subgrains. The results are discussed in terms of the evolution of the average diameter of subgrains and the average disorientation in the microstructure.

Published

2024