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Efficient Composite Infrared Spectroscopy: Combining the Double-Harmonic Approximation with Machine Learning Potentials

Philipp Pracht, Yuthika Pillai, Venkat Kapil, Gábor Cśanyi, Nils Gönnheimer, Martin Vondrák, Johannes T. Margraf, David J. Wales

2024Journal of Chemical Theory and Computation15 citationsDOIOpen Access PDF

Abstract

Vibrational spectroscopy is a cornerstone technique for molecular characterization and offers an ideal target for the computational investigation of molecular materials. Building on previous comprehensive assessments of efficient methods for infrared (IR) spectroscopy, this study investigates the predictive accuracy and computational efficiency of gas-phase IR spectra calculations, accessible through a combination of modern semiempirical quantum mechanical and transferable machine learning potentials. A composite approach for IR spectra prediction based on the double-harmonic approximation, utilizing harmonic vibrational frequencies in combination squared derivatives of the molecular dipole moment, is employed. This approach allows for methodical flexibility in the calculation of IR intensities from molecular dipoles and the corresponding vibrational modes. Various methods are systematically tested to suggest a suitable protocol with an emphasis on computational efficiency. Among these methods, semiempirical extended tight-binding (xTB) models, classical charge equilibrium models, and machine learning potentials trained for dipole moment prediction are assessed across a diverse data set of organic molecules. We particularly focus on the recently reported foundational machine learning potential MACE-OFF23 to address the accuracy limitations of conventional low-cost quantum mechanical and force-field methods. This study aims to establish a standard for the efficient computational prediction of IR spectra, facilitating the rapid and reliable identification of unknown compounds and advancing automated high-throughput analytical workflows in chemistry.

Topics & Concepts

Composite numberSpectroscopyInfraredHarmonicComputer scienceInfrared spectroscopyArtificial intelligenceMachine learningMaterials sciencePhysicsBiological systemChemical physicsAlgorithmOpticsQuantum mechanicsBiologySpectroscopy Techniques in Biomedical and Chemical ResearchSpectroscopy and Laser ApplicationsSpectroscopy and Quantum Chemical Studies
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