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Bibliographic Details
Main Authors: Tyner, Alexander C., Pathapati, Avinash, Balatsky, Alexander V.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.27879
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author Tyner, Alexander C.
Pathapati, Avinash
Balatsky, Alexander V.
author_facet Tyner, Alexander C.
Pathapati, Avinash
Balatsky, Alexander V.
contents The potential to utilize metal-organic frameworks as a replacement for rare earth materials as well as in technological applications has prompted increased interested in this material class. The simulation of organic materials, including metal-organic frameworks (MOFs), represents a computational challenge due to an increased average number of atoms in the unit cell. Compounding this challenge, modern materials databases are generally limited to inorganic structures due to their utility in modern technologies such as batteries and integrated circuits. Machine-learning tools appear ideally suited to study these systems. However, organic materials are generally underrepresented in the training sets of foundational models. In this work we leverage the the Organic Materials Database (OMDB) to create a training dataset comprised of more than 15,000 single-point first-principles computations for finetuning machine learned interatomic potentials. Specifically, we fine tune CHGNet and implement a site substitution workflow to identify novel, highly magnetic, MOFs from structural prototypes within the QMOF database.
format Preprint
id arxiv_https___arxiv_org_abs_2604_27879
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Generation of magnetic metal-organic frameworks
Tyner, Alexander C.
Pathapati, Avinash
Balatsky, Alexander V.
Materials Science
The potential to utilize metal-organic frameworks as a replacement for rare earth materials as well as in technological applications has prompted increased interested in this material class. The simulation of organic materials, including metal-organic frameworks (MOFs), represents a computational challenge due to an increased average number of atoms in the unit cell. Compounding this challenge, modern materials databases are generally limited to inorganic structures due to their utility in modern technologies such as batteries and integrated circuits. Machine-learning tools appear ideally suited to study these systems. However, organic materials are generally underrepresented in the training sets of foundational models. In this work we leverage the the Organic Materials Database (OMDB) to create a training dataset comprised of more than 15,000 single-point first-principles computations for finetuning machine learned interatomic potentials. Specifically, we fine tune CHGNet and implement a site substitution workflow to identify novel, highly magnetic, MOFs from structural prototypes within the QMOF database.
title Generation of magnetic metal-organic frameworks
topic Materials Science
url https://arxiv.org/abs/2604.27879