Physical-information machine learning for strength and ductility prediction of metastable β titanium alloys
Shenyang University of Technology · Northwest Institute For Non-Ferrous Metal Research · +1 more institution
Abstract
Machine learning for predicting metastable β titanium alloy properties suffers from limited generalisation, unreliable extrapolation beyond data boundaries, and inadequate modelling of nonlinear effects of process parameters. This study proposes a physics-informed machine learning approach incorporating intrinsic physical attributes and phase transformation kinetics. Using 496 samples, it achieves R2 = 0.95 for ultimate tensile strength (UTS) and 0.90 for elongation (El), accurately predicting out-of-boundary alloys with similar heat treatment responses within 5.0% UTS and 2.5% El error. This approach reduces reliance on data completeness and complex algorithms, providing an accurate, generalisable path to…
Citation impact
- FWCI
- 48.37
- Percentile
- 100%
- References
- 42
Authors
8Topics & keywords
- Titanium alloy
- Extrapolation
- Ultimate tensile strength
- Ductility (Earth science)
- Titanium
- Metastability
- Alloy
- Elongation