Honors Theses
Date of Award
Spring 5-9-2024
Document Type
Undergraduate Thesis
Department
Chemistry and Biochemistry
First Advisor
Ryan Fortenberry
Second Advisor
Nathan Hammer
Third Advisor
Gregory Tschumper
Relational Format
Thesis
Abstract
The quest for faster computation of anharmonic vibrational frequencies of both ground and excited electronic states has led to combining coupled cluster theory harmonic force constants with density functional theory (DFT) cubic and quartic force constants for defining a quartic force field (QFF) utilized in conjunction with vibrational perturbation theory at second order (VPT2). This work shows that explicitly correlated coupled cluster theory at the singles, doubles, and perturbative triples level [CCSD(T)-F12] provides accurate anharmonic vibrational frequencies and rotational constants when conjoined with any of B3LYP, CAM-B3LYP, BHandHLYP, PBE0, and ωB97XD for roughly one-quarter of the computational time of the CCSD(T)-F12 QFF alone for our test set. As the number of atoms in the molecule increases, however, the anharmonic terms become a greater portion of the QFF, and the cost comparison improves with HOCO+ and formic acid requiring less than 15% and 10% of the time, respectively. In electronically excited states, PBE0 produces more consistently accurate results. Additionally, as the size of the molecule and, in turn, QFF increases, the cost savings for utilizing such a hybrid approach for both ground and excited state computations grows. As such, these methods are promising for predicting accurate rovibrational spectral properties for electronically excited states. In cases where well-behaved potentials for a small selection of targeted excited states are needed, such an approach should reduce the computational cost compared to methods requiring semi-global potential surfaces or variational treatments of the rovibronic Hamiltonian. Such applications include spectral characterization of comets, exoplanets, or any situation in which gas phase molecules are being excited by UV-Vis radiation.
Recommended Citation
Garrett, Noah R., "Theoretical Spectroscopic Predictions of Electronically Excited States" (2024). Honors Theses. 3078.
https://egrove.olemiss.edu/hon_thesis/3078
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