Litcius/Paper detail

Stacking fault energy prediction for austenitic steels: thermodynamic modeling vs. machine learning

Xin Wang, Wei Xiong

2020Science and Technology of Advanced Materials47 citationsDOIOpen Access PDF

Abstract

Stacking fault energy (SFE) is of the most critical microstructure attribute for controlling the deformation mechanism and optimizing mechanical properties of austenitic steels, while there are no accurate and straightforward computational tools for modeling it. In this work, we applied both thermodynamic modeling and machine learning to predict the stacking fault energy (SFE) for more than 300 austenitic steels. The comparison indicates a high need of improving low-temperature CALPHAD (CALculation of PHAse Diagrams) databases and interfacial energy prediction to enhance thermodynamic model reliability. The ensembled machine learning algorithms provide a more reliable prediction compared with thermodynamic and empirical models. Based on the statistical analysis of experimental results, only Ni and Fe have a moderate monotonic influence on SFE, while many other elements exhibit a complex effect that their influence on SFE may change with the alloy composition.

Topics & Concepts

Stacking-fault energyAusteniteCALPHADMaterials scienceMachine learningEnergy (signal processing)Fault (geology)Artificial intelligenceStackingDeformation (meteorology)Monotonic functionAlgorithmStacking faultDeformation mechanismThermodynamicsMaterial propertiesPhase (matter)Computer scienceMicrostructureStatistical modelAlloyMechanism (biology)Probabilistic logicPhase diagramMetallurgyStatistical learning theoryMachine Learning in Materials ScienceMicrostructure and Mechanical Properties of SteelsHigh Temperature Alloys and Creep