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How Reliable Are Modern Density Functional Approximations to Simulate Vibrational Spectroscopies?

Sebastian P. Sitkiewicz, Robert Zaleśny, Eloy Ramos‐Cordoba, Josep M. Luis, Eduard Matito

2022The Journal of Physical Chemistry Letters25 citationsDOIOpen Access PDF

Abstract

We show that properties of molecules with low-frequency modes calculated with density functional approximations (DFAs) suffer from spurious oscillations along the nuclear displacement coordinate due to numerical integration errors. Occasionally, the problem can be alleviated using extensive integration grids that compromise the favorable cost-accuracy ratio of DFAs. Since spurious oscillations are difficult to predict or identify, DFAs are exposed to severe performance errors in IR and Raman intensities and frequencies or vibrational contributions to any molecular property. Using Fourier spectral analysis and digital signal processing techniques, we identify and quantify the error due to these oscillations for 45 widely used DFAs. LC-BLYP and BH&H are revealed as the only functionals showing robustness against the spurious oscillations of various energy, dipole moment, and polarizability derivatives with respect to a nuclear displacement coordinate. Given the ubiquitous nature of molecules with low-frequency modes, we warrant caution in using modern DFAs to simulate vibrational spectroscopies.

Topics & Concepts

Spurious relationshipRobustness (evolution)Computer scienceDipolePolarizabilityStatistical physicsComputational physicsPhysicsQuantum mechanicsMoleculeChemistryGeneBiochemistryMachine learningSpectroscopy and Quantum Chemical StudiesMolecular spectroscopy and chiralitySpectroscopy and Laser Applications
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