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Main Authors: Hörmann, Lukas, Stark, Wojciech G., Maurer, Reinhard J.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.19814
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author Hörmann, Lukas
Stark, Wojciech G.
Maurer, Reinhard J.
author_facet Hörmann, Lukas
Stark, Wojciech G.
Maurer, Reinhard J.
contents Nanoscale design of surfaces and interfaces is essential for modern technologies like organic LEDs, batteries, fuel cells, superlubricating surfaces, and heterogeneous catalysis. However, these systems often exhibit complex surface reconstructions and polymorphism, with properties influenced by kinetic processes and dynamic behavior. A lack of accurate and scalable simulation tools has limited computational modeling of surfaces and interfaces. Recently, machine learning and data-driven methods have expanded the capabilities of theoretical modeling, enabling, for example, the routine use of machine-learned interatomic potentials to predict energies and forces across numerous structures. Despite these advances, significant challenges remain, including the scarcity of large, consistent datasets and the need for computational and data-efficient machine learning methods. Additionally, a major challenge lies in the lack of accurate reference data and electronic structure methods for interfaces. Density Functional Theory, while effective for bulk materials, is less reliable for surfaces, and too few accurate experimental studies on interface structure and stability exist. Here, we will sketch the current state of data-driven methods and machine learning in computational surface science and provide a perspective on how these methods will shape the field in the future.
format Preprint
id arxiv_https___arxiv_org_abs_2503_19814
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Machine Learning and Data-Driven Methods in Computational Surface and Interface Science
Hörmann, Lukas
Stark, Wojciech G.
Maurer, Reinhard J.
Materials Science
Computational Physics
Nanoscale design of surfaces and interfaces is essential for modern technologies like organic LEDs, batteries, fuel cells, superlubricating surfaces, and heterogeneous catalysis. However, these systems often exhibit complex surface reconstructions and polymorphism, with properties influenced by kinetic processes and dynamic behavior. A lack of accurate and scalable simulation tools has limited computational modeling of surfaces and interfaces. Recently, machine learning and data-driven methods have expanded the capabilities of theoretical modeling, enabling, for example, the routine use of machine-learned interatomic potentials to predict energies and forces across numerous structures. Despite these advances, significant challenges remain, including the scarcity of large, consistent datasets and the need for computational and data-efficient machine learning methods. Additionally, a major challenge lies in the lack of accurate reference data and electronic structure methods for interfaces. Density Functional Theory, while effective for bulk materials, is less reliable for surfaces, and too few accurate experimental studies on interface structure and stability exist. Here, we will sketch the current state of data-driven methods and machine learning in computational surface science and provide a perspective on how these methods will shape the field in the future.
title Machine Learning and Data-Driven Methods in Computational Surface and Interface Science
topic Materials Science
Computational Physics
url https://arxiv.org/abs/2503.19814