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Accelerating Molecular Vibrational Spectra Simulations with a Physically Informed Deep Learning Model

Yuzhuo Chen, Sebastian V. Pios, Maxim F. Gelin, Lipeng Chen

2024Journal of Chemical Theory and Computation12 citationsDOI

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 multitask ML surrogate model termed Vibrational Spectra Neural Network (VSpecNN), to accurately calculate infrared (IR) and Raman spectra based on dipole moments and polarizabilities obtained on-the-fly via ML-enhanced molecular dynamics simulations. The methodology is applied to pyrazine, a prototypical polyatomic chromophore. The VSpecNN-predicted energies are well within the chemical accuracy (1 kcal/mol), and the errors for VSpecNN-predicted forces are only half of those obtained from a popular high-performance ML model. Compared to the ab initio reference, the VSpecNN-predicted frequencies of IR and Raman spectra differ only by less than 5.87 cm –1, and the intensities of IR spectra and the depolarization ratios of Raman spectra are well reproduced. The VSpecNN model developed in this work highlights the importance of constructing highly accurate neural network potentials for predicting molecular vibrational spectra.

Topics & Concepts

Raman spectroscopySpectral linePolyatomic ionDipoleMolecular vibrationInfraredMolecular dynamicsInfrared spectroscopyChemistryMolecular physicsComputational chemistryPhysicsMoleculeOpticsQuantum mechanicsOrganic chemistryMachine Learning in Materials ScienceComputational Drug Discovery MethodsSpectroscopy and Quantum Chemical Studies
Accelerating Molecular Vibrational Spectra Simulations with a Physically Informed Deep Learning Model | Litcius