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Meeting	MS&T22: Materials Science & Technology
Symposium	Ceramics and Glasses Modeling by Simulations and Machine Learning
Presentation Title	Machine Learning-Derived Atomistic Potentials for Y₂Si₂O₇ and Yb₂Si₂O₇
Author(s)	Cameron J. Bodenschatz, Wissam A. Saidi, Jamesa L. Stokes
On-Site Speaker (Planned)	Cameron J. Bodenschatz
Abstract Scope	Incorporation of SiC/SiC ceramic matrix composite (CMC) hot section components into aircraft engines promises to increase efficiency and safety. However, SiC/SiC CMCs are subject to water vapor-induced oxidation and recession at the high temperatures of engine operation, and thus environmental barrier coatings (EBCs) are required to reduce this degradation and enable their widespread adoption. An understanding of EBCs failure mechanisms, including thermochemical and thermomechanical mechanisms, is essential as coating degradation leads to reduced CMC component service life. Computational modeling approaches can provide insight into EBC material properties important for coating design. However, density functional theory (DFT) is computationally expensive and atomistic potentials are lacking for materials of interest. In this work, we utilize a machine learning approach and DFT training data to parameterize atomistic potentials for two candidate EBC materials, Y₂Si₂O₇ and Yb₂Si₂O₇. These potentials enable near DFT-accurate calculations of thermodynamic and thermomechanical properties essential to EBC design.

OTHER PAPERS PLANNED FOR THIS SYMPOSIUM

A Physics Informed Machine Learning Approach to Predict Glass Forming Ability

D-7: Development of Structural Descriptors to Predict Dissolution Rate of Volcanic Glasses: Molecular Dynamic Simulations

D-8: Molecular Dynamic Simulations of Polymer Derived Ceramics

Data-driven Prediction of Room Temperature Density of Multicomponent Silicate-based Glasses

Data Driven Design and Enhancement of Machinable Glass Ceramics

Developing ReaxFF for Simulation of Silicon Carbonitride Polymer-derived Ceramics

In-Silico Simulations of Polymer Pyrolysis

Machine Learning-Derived Atomistic Potentials for Y₂Si₂O₇ and Yb₂Si₂O₇

Machine Learning Defect Properties of Semiconductors

Machine Learning to Design and Discover Sustainable Cementitious Binders: Learning from Small Databases and Developing Closed-form Analytical Models

Molecular Dynamics Simulation of Tellurite Glasses

Molecular Dynamics Study of Domain Switching Dynamics in KNbO3 and BaTiO3

Natural Language Processing Aided Understanding of Material Science Literature

Pore-resolved Simulations of Chemical Vapor Infiltration in 3D Printed Preforms and the Kinetic Regimes

Predicting and Accessing Metastable Phases

Predicting the Dynamics of Atoms in Glass-Forming Liquids by a Surrogate Machine-Learned Simulator

Quantifying the Local Structure of Metallic Glass as a Function of Composition and Atomic Size

Using Machine Learning Empirical Potentials to Investigate Interdiffusion at Metal-Chalcogenide Alloy Interfaces

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