Litcius/Paper detail

Coupling physics in machine learning to predict properties of high-temperatures alloys

Jian Peng, Yukinori Yamamoto, Jeffrey A. Hawk, Edgar Lara-Curzio, Dongwon Shin

2020npj Computational Materials90 citationsDOIOpen Access PDF

Abstract

Abstract High-temperature alloy design requires a concurrent consideration of multiple mechanisms at different length scales. We propose a workflow that couples highly relevant physics into machine learning (ML) to predict properties of complex high-temperature alloys with an example of the 9–12 wt% Cr steels yield strength. We have incorporated synthetic alloy features that capture microstructure and phase transformations into the dataset. Identified high impact features that affect yield strength of 9Cr from correlation analysis agree well with the generally accepted strengthening mechanism. As a part of the verification process, the consistency of sub-datasets has been extensively evaluated with respect to temperature and then refined for the boundary conditions of trained ML models. The predicted yield strength of 9Cr steels using the ML models is in excellent agreement with experiments. The current approach introduces physically meaningful constraints in interrogating the trained ML models to predict properties of hypothetical alloys when applied to data-driven materials.

Topics & Concepts

Consistency (knowledge bases)Coupling (piping)Yield (engineering)WorkflowAlloyMaterials scienceArtificial intelligenceMachine learningTitanium alloyMicrostructurePhase (matter)Computer scienceExperimental dataBoundary (topology)Phase boundaryMaterial propertiesCurrent (fluid)AlgorithmStatistical physicsExtrapolationMechanical engineeringWork (physics)Machine Learning in Materials ScienceModel Reduction and Neural NetworksMicrostructure and Mechanical Properties of Steels