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Meeting 2021 TMS Annual Meeting & Exhibition
Symposium AI/Data Informatics: Applications and Uncertainty Quantification at Atomistics and Mesoscales
Presentation Title Building a Better Database to Learn From; Application to Interatomic Potentials
Author(s) Mitchell Wood, Nicholas Lubbers, Danny Perez, Charles Sievers
On-Site Speaker (Planned) Mitchell Wood
Abstract Scope While many research challenges in material physics, chemistry and biology lie just out of reach on current peta-scale machines due to length and time restrictions inherent to Molecular Dynamics, questions of the accuracy of our simulations will continue to linger. A recent trend is to develop machine learned(ML) IAP that demonstrate ab initio levels of accuracy, but are far more computationally efficient. The starting point for all ML applications is a collection of training data which constrains the learned parameters of a model form, but most often which data is included as training is skewed by user-defined heuristics and is liable to fail when extrapolating beyond where training was supplied. In order to provide accurate and transferrable ML-IAP, we have focused our efforts on developing methods to generate training sets that can be used by common computing clusters as well as leadership computing platforms.
Proceedings Inclusion? Planned:

OTHER PAPERS PLANNED FOR THIS SYMPOSIUM

A Bayesian Optimization Framework for Exploring the Grain Boundary Manifold
A Machine Learning Investigation of Crystallographic Parameters for Abnormal Grain Growth
A Probabilistic Approach with Built-in Uncertainty Quantification for the Calibration of a Superelastic Constitutive Model from Full-field Strain Data
A Sensitivity Analysis of Microstructure-Based Model for U-10Mo Hot Rolling and Annealing
Accelerating High Throughput Materials Simulation Studies Using Machine Learning Based Application Programming Interface (API)
Accelerating Phase-field Predictions via Machine Learning Trained Surrogate Models
Accelerating the Discovery of Self-Reporting Redox-active Materials Using Quantum Chemistry Guided Machine Learning
Accuracy, Uncertainty, Inspectability: The Benefits of Compositionally-restricted Attention-based Networks
AI Guided Discovery of Self-assembly Peptide Sequences using Monte Carlo Tree Search and Coarse-grained Simulations
AI Guided High-throughput Exploration of Potential Energy Surfaces
Are We Making Progress on ML Algorithms for Structure-property Relationships? Using MatBench as a Test Bed
Bayesian Inference and Uncertainty Quantification of Grain Boundary Properties
Building a Better Database to Learn From; Application to Interatomic Potentials
Coupling Machine Learning and Global Structure Optimization in GASP 2.0
Data Science Approaches to Develop Predictive Models for Energy-relevant Materials
Decision Trees in Continuous Action Space for High-throughput Exploration of Potential Energy Surfaces
Discovery and Classification of Double Spinel Chemical Space
Exploring Metastability and Mapping Metastable Phase Diagrams Using Machine Learning
Fast Crystal Structure Reconstruction and Prediction Method: Based on X-ray Diffraction Dataset and Neural Network
Finding and Sharing Atomistic Materials Data and Software with the NIST Materials Resource Registry
Harnessing Materials Data and Simulation Capabilities for the Accelerated Discovery of Photocathode Materials
Inverse Design of Energy Storage Materials via Active Learning
Machine Learning Approach of Molecular Dynamics Simulations for Body-Centered Cubic Zirconium
Machine Learning for Predicting Grain Boundary Properties
Machine Learning Guided Discovery of Novel Oxide Perovskites for Scintillator Applications
Machine Learning Prediction of Defect Formation Energies
Microstructure-driven Parameter Calibration for Mesoscale Simulation
Mining Structure-property Linkages in Nonporous Materials Using Interpretative Deep Learning Approach
Model Comparison and Uncertainty Prediction for ML Models of Crystalline Solids Material Properties
Multi-fidelity Machine-learning with Uncertainty Quantification and Bayesian Optimization for Materials Design: Application to Random Alloys
Neural Network Reactive Force Field for C, H, N, O Systems
Parsimonious Neural Networks Learn Classical Mechanics and an Accurate Time Integrator
Predicting Adsorption Energies and Surface Pourbaix Diagram of Metal NPs by GCNN Method
Quantifying RAMPAGE Interatomic Potentials for Metal Alloys
Simultaneous Development and Robust Optimization of a Microstructure Dependent Material Model: Leveraging Sequential Monte-Carlo Methods to Enhance Symbolic Regression Analysis
Solving Stochastic Inverse Problems for Structure-Property Linkages Using Data-Consistent Inversion
Uncertainty Quantification in Computational Thermodynamics - From the Atomistic to the Continuum Scale
Uncertainty Quantification of Microstructures with a New Technique: Shape Moment Invariants
Use of Atomistic Based Informatics to Model Ionic Bombardment to Synthesize Boron Carbides
De Novo Design of Therapeutic Agents Against COVID-19 Using Artificial Intelligence

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