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Thermal conductivity predictions with foundation atomistic models

Balázs Póta1*, Paramvir Ahlawat1, Gábor Csányi2, Michele Simoncelli1*

1 Theory of Condensed Matter Group of the Cavendish Laboratory, University of Cambridge, Cambridge, UK

2 Engineering Laboratory, University of Cambridge, Cambridge, UK

* Corresponding authors emails: bp443@cam.ac.uk, ms2855@cam.ac.uk
DOI10.24435/materialscloud:2d-4b [version v1]

Publication date: Oct 22, 2024

How to cite this record

Balázs Póta, Paramvir Ahlawat, Gábor Csányi, Michele Simoncelli, Thermal conductivity predictions with foundation atomistic models, Materials Cloud Archive 2024.171 (2024), https://doi.org/10.24435/materialscloud:2d-4b

Description

Advances in machine learning have led to the development of foundation models for atomistic materials chemistry, enabling quantum-accurate descriptions of interatomic forces across diverse compounds at reduced computational cost. Hitherto, these models have been benchmarked relying on descriptors based on atoms' interaction energies or harmonic vibrations; their accuracy and efficiency in predicting observable and technologically relevant heat-conduction properties remains unknown. Here, we introduce a framework that leverages foundation models and the Wigner formulation of heat transport to overcome the major bottlenecks of current methods for designing heat-management materials: high cost, limited transferability, or lack of physics awareness. We present the standards needed to achieve first-principles accuracy in conductivity predictions through model's fine-tuning, discussing benchmark metrics and precision/cost trade-offs. We apply our framework to a database of solids with diverse compositions and structures, demonstrating its potential to discover materials for next-gen technologies ranging from thermal insulation to neuromorphic computing.

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Files

File name Size Description
data.zip
MD5md5:b55af517e53a86693990ab00f783d3e4
359.8 MiB Dataset containing reference DFT thermal conductivity results, as well as scripts and data used for fine-tuning.

License

Files and data are licensed under the terms of the following license: Academic Software Licence ("ASL").
Metadata, except for email addresses, are licensed under the Creative Commons Attribution Share-Alike 4.0 International license.

External references

Preprint (Supporting dataset for "Thermal Conductivity Predictions with Foundation Atomistic Models")
B. Póta, P. Ahlawat, G. Csányi, M. Simoncelli, arXiv preprint, arXiv:2408.00755 (2024) doi:10.48550/arXiv.2408.00755

Keywords

thermal conductivity foundation machine learning potential wigner transport equation interatomic potential fine-tuning matbench-discovery

Version history:

2024.171 (version v1) [This version] Oct 22, 2024 DOI10.24435/materialscloud:2d-4b