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A deep-neural network potential to study transformation-induced plasticity in zirconia

Jinyu Zhang, Gaël Huynh, Fu‐Zhi Dai, Tristan Albaret, Shihao Zhang, Shigenobu Ogata, David Rodney

2024Journal of the European Ceramic Society15 citationsDOIOpen Access PDF

Abstract

Zirconia (ZrO2) ceramics uniquely exhibit transformation-induced plasticity, allowing plastic deformation prior to failure, setting them apart from most other ceramics. However, our understanding of ZrO2 plasticity is hindered by the challenge of simulating stress-induced atomic-scale phase transformations, owing to lack of an efficient interatomic potential accurately representing polymorphism and phase changes in ZrO2. In this work, we introduce a novel deep neural network interatomic potential, DP-ZrO2, constructed using a concurrent-learning approach. DP-ZrO2 reproduces properties of various ZrO2 phases, matching their phase diagrams as well as transformation pathways with accuracy comparable to ab initio density functional theory. Leveraging DP-ZrO2, we conducted molecular dynamics simulations of temperature-induced interphase boundary migration and nanocompression. These simulations demonstrate the potential’s efficiency and applicability in studying deformation microstructures involving phase transformations in ZrO2. Our approach opens the door to large-scale simulations under complex loading conditions, which will shed light on the conditions favouring ZrO2 transformation-induced plasticity.

Topics & Concepts

Materials scienceTransformation (genetics)Cubic zirconiaPlasticityArtificial neural networkArtificial intelligenceComposite materialComputer scienceBiologyCeramicBiochemistryGeneAdvanced materials and compositesMachine Learning in Materials ScienceX-ray Diffraction in Crystallography
A deep-neural network potential to study transformation-induced plasticity in zirconia | Litcius