Scope |
This symposium features novel methods and new discoveries for understanding all aspects of material fatigue. It brings together scientists and engineers from all over the world to present their latest work on current issues in: characterizing and simulating fatigue damage; identifying microstructural weak links; enhancing fatigue strength and resistance; reporting on quantitative relationships among processing, microstructure, environment, and fatigue properties; and providing methods to perform life predictions. This symposium further provides a platform for fostering new ideas about fatigue at multiple scales and in multiple environments, numerically, theoretically, and experimentally.
The symposium organizers are committed to achieving excellence in 2023 by providing a comprehensive symposium that highlights the relevant fatigue topics to academic and industry research.
The proposed 2023 TMS symposium will be organized into six sessions. One of the sessions, related to microstructure-based fatigue studies on additive-manufactured materials, will be jointly organized with the AM Fatigue & Fracture symposium to prevent overlapping topics at the TMS2023 meeting. The proposed six sessions will be carried out over three full days. Throughout the six sessions, there will be an estimated 50 oral presentations, with 2-4 of those being keynote presentations on relevant topics. Researchers who achieved new findings in fundamental and industrial fatigue topics will be given the opportunity to provide an invited talk. Additionally, a poster session will be held to supplement the oral presentations and to encourage student involvement. Prizes for best posters will be awarded. A possible edited volume of extended articles on select topics discussed in this symposium will be evaluated during the meeting. Topics of interest may include (but are not limited to):
* Predictive methods for fatigue properties. For instance, digital twin approaches; data-driven, data-centric and high-throughput methods; multiscale modeling approaches.
* Advanced experimental characterization of microstructurally driven fatigue behavior. For instance, emerging characterization methods; multi-modal, correlative and 3D measurements.
* Fatigue deformation processes. For instance, damage initiation, crack propagation, and plastic localization.
* Fatigue properties in extreme environments. For instance, Fatigue properties of novel alloys for extreme environments; fatigue properties at high or cryogenic temperature; very high cycle fatigue.
* Fatigue studies and design under the process-(micro)structure-properties-performance paradigm.
* Microstructure-based fatigue studies on additive-manufactured Materials. |