| About this Abstract |
| Meeting |
2022 TMS Annual Meeting & Exhibition
|
| Symposium
|
AI/Data Informatics: Computational Model Development, Validation, and Uncertainty Quantification
|
| Presentation Title |
Data Driven Approach to Design/Discover Intercalating Ions and Layered Materials for Metal-ion Batteries |
| Author(s) |
Shayani Parida, Avanish Mishra, Arthur Dobley, C Barry Carter, Avinash Dongare |
| On-Site Speaker (Planned) |
Shayani Parida |
| Abstract Scope |
This study utilizes data-driven machine learning methods to find alternative 2D materials and intercalating ions beyond Li for metal-ion batteries with high-power efficiencies. A dataset is constructed by performing first-principles density functional theory (DFT) simulations to estimate theoretical capacities and voltages by calculating the binding energies of metal ions on 2D materials. A tree-based regression model is developed to predict the binding energies with unprecedented accuracy. The model suggests that atomic electronegativities and number of valence electrons bear a strong correlation with binding energy. The generated dataset also provides insight into structural accommodations that can be expected upon ion intercalation on various 2D materials. Additionally, a binding energy and structural deformation-based classification model is developed to screen anode materials for the next-generation batteries. The model selects intercalating ion and 2D material pairs that are suitable for batteries, based on calculated voltage and volumetric changes in the 2D material upon intercalation. |
| Proceedings Inclusion? |
Planned: |
| Keywords |
Energy Conversion and Storage, Machine Learning, Modeling and Simulation |