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Main Authors: Cheula, Raffaele, Andersen, Mie, Kitchin, John R.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.24482
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author Cheula, Raffaele
Andersen, Mie
Kitchin, John R.
author_facet Cheula, Raffaele
Andersen, Mie
Kitchin, John R.
contents Determining transition states (TSs) of surface reactions is central to understanding and designing heterogeneous catalysts but remains computationally prohibitive with density functional theory (DFT). While machine learning potentials (MLPs) offer significant speedups, task-specific models have limited transferability across catalytic systems, and universal MLPs (uMLPs) lack the accuracy needed for reactive configurations. Here, we present a workflow based on active learning to iteratively fine-tune uMLPs for DFT-quality TS search. Using 250 TSs from the CO2 hydrogenation reaction network on metal and single-atom alloy surfaces, we first benchmark TS search algorithms, identifying the Sella algorithm as most robust, and propose a modification (Bond-Aware Sella) that substantially improves its success rate. We then explore sequential and batch active-learning strategies for fine-tuning and show that DFT-quality TS structures can be found using only 8 DFT single-point calculations on average per structure. This demonstrates the viability of fine-tuned uMLPs for high-throughput catalyst screening.
format Preprint
id arxiv_https___arxiv_org_abs_2603_24482
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Fine-tuning universal machine learning potentials for transition state search in surface catalysis
Cheula, Raffaele
Andersen, Mie
Kitchin, John R.
Materials Science
Determining transition states (TSs) of surface reactions is central to understanding and designing heterogeneous catalysts but remains computationally prohibitive with density functional theory (DFT). While machine learning potentials (MLPs) offer significant speedups, task-specific models have limited transferability across catalytic systems, and universal MLPs (uMLPs) lack the accuracy needed for reactive configurations. Here, we present a workflow based on active learning to iteratively fine-tune uMLPs for DFT-quality TS search. Using 250 TSs from the CO2 hydrogenation reaction network on metal and single-atom alloy surfaces, we first benchmark TS search algorithms, identifying the Sella algorithm as most robust, and propose a modification (Bond-Aware Sella) that substantially improves its success rate. We then explore sequential and batch active-learning strategies for fine-tuning and show that DFT-quality TS structures can be found using only 8 DFT single-point calculations on average per structure. This demonstrates the viability of fine-tuned uMLPs for high-throughput catalyst screening.
title Fine-tuning universal machine learning potentials for transition state search in surface catalysis
topic Materials Science
url https://arxiv.org/abs/2603.24482