A Database of Ultrastable MOFs Reassembled from Stable Fragments with Machine Learning Models

• URL: http://arxiv.org/abs/2210.14191v1
• Date: Tue, 25 Oct 2022 17:38:42 GMT
• Title: A Database of Ultrastable MOFs Reassembled from Stable Fragments with Machine Learning Models
• Authors: Aditya Nandy, Shuwen Yue, Changhwan Oh, Chenru Duan, Gianmarco G. Terrones, Yongchul G. Chung, and Heather J. Kulik
• Abstract summary: We leverage community knowledge and machine learning models to identify metal-organic frameworks (MOFs) that are thermally stable and stable upon activation. We make a new hypothetical MOF database of over 50,000 structures that samples orders of magnitude more connectivity nets and inorganic building blocks than prior databases. This database shows an order of magnitude enrichment of ultrastable MOF structures that are stable upon activation and more than one standard deviation more thermally stable than the average experimentally characterized MOF.
• Score: 0.3710026260502075
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: High-throughput screening of large hypothetical databases of metal-organic frameworks (MOFs) can uncover new materials, but their stability in real-world applications is often unknown. We leverage community knowledge and machine learning (ML) models to identify MOFs that are thermally stable and stable upon activation. We separate these MOFs into their building blocks and recombine them to make a new hypothetical MOF database of over 50,000 structures that samples orders of magnitude more connectivity nets and inorganic building blocks than prior databases. This database shows an order of magnitude enrichment of ultrastable MOF structures that are stable upon activation and more than one standard deviation more thermally stable than the average experimentally characterized MOF. For the nearly 10,000 ultrastable MOFs, we compute bulk elastic moduli to confirm these materials have good mechanical stability, and we report methane deliverable capacities. Our work identifies privileged metal nodes in ultrastable MOFs that optimize gas storage and mechanical stability simultaneously.

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