Volume 249, 2024

First-principles spectroscopy of aqueous interfaces using machine-learned electronic and quantum nuclear effects

Abstract

Vibrational spectroscopy is a powerful approach to visualising interfacial phenomena. However, extracting structural and dynamical information from vibrational spectra is a challenge that requires first-principles simulations, including non-Condon and quantum nuclear effects. We address this challenge by developing a machine-learning enhanced first-principles framework to speed up predictive modelling of infrared, Raman, and sum-frequency generation spectra. Our approach uses machine learning potentials that encode quantum nuclear effects to generate quantum trajectories using simple molecular dynamics efficiently. In addition, we reformulate bulk and interfacial selection rules to express them unambiguously in terms of the derivatives of polarisation and polarisabilities of the whole system and predict these derivatives efficiently using fully-differentiable machine learning models of dielectric response tensors. We demonstrate our framework's performance by predicting the IR, Raman, and sum-frequency generation spectra of liquid water, ice and the water–air interface by achieving near quantitative agreement with experiments at nearly the same computational efficiency as pure classical methods. Finally, to aid the experimental discovery of new phases of nanoconfined water, we predict the temperature-dependent vibrational spectra of monolayer water across the solid-hexatic-liquid phases transition.

Graphical abstract: First-principles spectroscopy of aqueous interfaces using machine-learned electronic and quantum nuclear effects

Associated articles

Article information

Article type
Paper
Submitted
30 May 2023
Accepted
18 Jul 2023
First published
20 Jul 2023
This article is Open Access
Creative Commons BY-NC license

Faraday Discuss., 2024,249, 50-68

First-principles spectroscopy of aqueous interfaces using machine-learned electronic and quantum nuclear effects

V. Kapil, D. P. Kovács, G. Csányi and A. Michaelides, Faraday Discuss., 2024, 249, 50 DOI: 10.1039/D3FD00113J

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