Invertible crystallographic representation for inorganic crystals via new API
This project aims to improve thermoelectric material identification and evaluation by utilizing the advanced machine-learning framework. We utilize the vast dataset of the Materials Project database, focusing on material properties including formation energy, band gap, and crystal structure, b...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2024
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| Online Access: | https://hdl.handle.net/10356/174589 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This project aims to improve thermoelectric material identification and evaluation by
utilizing the advanced machine-learning framework. We utilize the vast dataset of the
Materials Project database, focusing on material properties including formation energy,
band gap, and crystal structure, by combining Variational Autoencoders (VAEs) with
semi-supervised learning approaches. Specifically, the approach develops a Fourier Transformed Crystal Properties (FTCP) representation that is carefully designed for
deep learning applications. This representation enables our model to encode complex,
high-dimensional data into a concise latent space. From this latent space, we develop
new materials by the manipulation of latent variables and their subsequent decoding,
revealing materials with improved thermoelectric characteristics, such as optimized
Seebeck coefficients.
This method improves the model's learning process and prediction ability by utilizing
both labelled and unlabeled data, going beyond traditional supervised learning. With
the help of advanced training strategies like dynamic learning rate adjustments and
thorough preparation processes like data normalization and augmentation, the model
demonstrates a remarkable ability to predict material attributes. Furthermore, the
interaction between different material properties and how that interaction affects
thermoelectric performance may be better understood using graphical analysis.
This project not only demonstrates the revolutionary potential of machine learning in
material science, but it had also established a new standard for the effective and scalable
search for advanced thermoelectric materials. Using the model's predictive capability,
we set out to investigate the wide range of possible materials to find and develop
materials that have the potential to revolutionize thermoelectric technology in the
future. Hence, this effort demonstrates the complementary nature of material science
and computational science and opens a new path for creative approaches to energy
conversion and management. |
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