Projects per year
Abstract
As the most important solvent, water has been at the center of interest since the advent of computer simulations. While early molecular dynamics and Monte Carlo simulations had to make use of simple model potentials to describe the atomic interactions, accurate ab initio molecular dynamics simulations relying on the first-principles calculation of the energies and forces have opened the way to predictive simulations of aqueous systems. Still, these simulations are very demanding, which prevents the study of complex systems and their properties. Modern machine learning potentials (MLPs) have now reached a mature state, allowing us to overcome these limitations by combining the high accuracy of electronic structure calculations with the efficiency of empirical force fields. In this Perspective, we give a concise overview about the progress made in the simulation of water and aqueous systems employing MLPs, starting from early work on free molecules and clusters via bulk liquid water to electrolyte solutions and solid-liquid interfaces.
Original language | English |
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Article number | 170901 |
Number of pages | 18 |
Journal | Journal of Chemical Physics |
Volume | 160 |
Issue number | 17 |
DOIs | |
Publication status | Published - 7 May 2024 |
Austrian Fields of Science 2012
- 103015 Condensed matter
- 103006 Chemical physics
- 103043 Computational physics
Projects
- 2 Active
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TACO: Taming Complexity in Materials Modeling
Diebold, U., Kresse, G., Mezger-Backus, E. H. G., Dellago, C. & Franchini, C.
1/03/21 → 28/02/25
Project: Research funding
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DCAFM : Doctoral College Advanced Functional Materials
Dellago, C., Ayala, P., Arndt, M., Bismarck, A., Franchini, C., Gonzalez Herrero, L., Kantorovich, S., Kotakoski, J., Kresse, G., Likos, C., Pichler, T. & Rennhofer, C.
1/10/20 → 30/09/24
Project: Research funding