English

Accelerating molecular vibrational spectra simulations with a physically informed deep learning model

Chemical Physics 2024-02-13 v1

Abstract

In recent years, machine learning (ML) surrogate models have emerged as an indispensable tool to accelerate simulations of physical and chemical processes. However, there is still a lack of ML models that can accurately predict molecular vibrational spectra. Here, we present a highly efficient high-dimensional neural network potentials (HD-NNP) architecture to accurately calculate infrared (IR) and Raman spectra based on dipole moments and polarizabilities obtained on-the-fly via ML-molecular dynamics (MD) simulations. The methodology is applied to pyrazine, a prototypical polyatomic chromophore. The HD-NNP predicted energies are well within the chemical accuracy (1 kcal/mol), and the errors for HD-NNP predicted forces are only one-half of those obtained from a popular high-performance ML model. Compared to the ab initio reference, the HD-NNP predicted frequencies of IR and Raman spectra differ only by less than 8.3 cm^(-1), and the intensities of IR spectra and the depolarizaiton ratios of Raman spectra are well reproduced. The HD-NNP architecture developed in this work highlights importance of constructing highly accurate NNPs for predicting molecular vibrational spectra.

Keywords

Cite

@article{arxiv.2402.06911,
  title  = {Accelerating molecular vibrational spectra simulations with a physically informed deep learning model},
  author = {Yuzhuo Chen and Sebastian V. Pios and Maxim F. Gelin and Lipeng Chen},
  journal= {arXiv preprint arXiv:2402.06911},
  year   = {2024}
}
R2 v1 2026-06-28T14:44:51.206Z