| About this Abstract |
| Meeting |
2025 TMS Annual Meeting & Exhibition
|
| Symposium
|
Bridging Scale Gaps in Multiscale Materials Modeling in the Age of Artificial Intelligence
|
| Presentation Title |
A Dislocation Density-Based Crystal Plasticity Finite Element Model for Predicting Creep Behavior in Lamellar Titanium-Aluminum Alloys |
| Author(s) |
Karel M. Ziminsky, Cheng Sun |
| On-Site Speaker (Planned) |
Karel M. Ziminsky |
| Abstract Scope |
This research seeks to utilize dislocation density evolution models to provide a physical basis to drive a mesoscale crystal plasticity finite element model to predict creep behavior. While other methods exist for predicting deformation behavior under creep loading, these are often limited to narrowly defined scales due to either computational expense or phenomenological constraints. This necessitates finding a middle ground of reducing the computation cost while retaining sufficient connection to the underlying physics and microstructure of the material. This dislocation-density-based crystal plasticity model will provide a more accurate and flexible tool than a traditional empirical creep model that can enable optimization of controllable microstructure characteristics for desired material performance such as creep resistance. This model will be used to help understand creep behavior in lamellar titanium-aluminum alloys and validated with strain behavior from experimental creep tests and x-ray diffraction analysis of samples post-test. |
| Proceedings Inclusion? |
Planned: |
| Keywords |
Computational Materials Science & Engineering, High-Temperature Materials, Modeling and Simulation |