Calculation of the Vibrational Spectra of Linear Tetrapyrroles. 2. Resonance Raman Spectra of Hexamethylpyrromethene Monomers

Abstract: The resonance Raman (RR) spectra of monomeric 3,3‘,4,4‘,5,5‘-hexamethylpyrromethene (HMPM) were measured upon excitation in resonance with the strong 436 nm absorption band. The experimental spectra were analyzed by comparison with calculated RR spectra that were obtained on the basis of scaled quantum chemical force fields in combination with the transform theory. The ground-state structure and force field of HMPM were calculated by density functional theory (DFT) using the B3LYP exchange functional and the 6… Show more

“…Obviously, the 15 N/ 14 N isotopic substitution causes a redistribution of the normal mode compositions in this region such that excited-state displacements of individual internal coordinates cancel each other. 27 A careful inspection of this region reveals that there are two weak bands at 1384 and 1371 cm 1 in the spectrum of P ž ( 15 N). The latter band may correspond to 1377 cm 1 P ž (D 2 O), which in P ž (H 2 O) may be at a higher wavenumber so that is hidden under the 1391 cm 1 envelope.…”

Resonance Raman spectroscopic study of the neutral flavin radical complex of DNA photolyase from Escherichia coli

“…Obviously, the 15 N/ 14 N isotopic substitution causes a redistribution of the normal mode compositions in this region such that excited-state displacements of individual internal coordinates cancel each other. 27 A careful inspection of this region reveals that there are two weak bands at 1384 and 1371 cm 1 in the spectrum of P ž ( 15 N). The latter band may correspond to 1377 cm 1 P ž (D 2 O), which in P ž (H 2 O) may be at a higher wavenumber so that is hidden under the 1391 cm 1 envelope.…”

Resonance Raman spectroscopic study of the neutral flavin radical complex of DNA photolyase from Escherichia coli

“…Applications of theoretical approaches to resonance Raman spectra of larger molecules have become feasible in recent years mainly due to the development of reliable methods for the calculation of ground-state vibrational modes and excited electronic states [479,480,493,501,503,509,544,545]. In particular the fact that frequency analyses based on density functional theory are very efficient [337] and yield harmonic frequencies that are usually in very good agreement with fundamental frequencies as obtained in experiment [528,546] made it possible to clarify intricate features in complicated vibrational spectra [446,547,548].…”

Chromophore-specific theoretical spectroscopy: From subsystem density functional theory to mode-specific vibrational spectroscopy

“…Further investigations led to the refinement of the transform theory of RRS by Rush and Peticolas, who applied it with success to different molecules of interest: uracil [69], metalloporphyrins and heme proteins [70]. Mroginski et al [71] used this approach to study linear tetrapyrroles, constituents of the chromophoric sites of various biological photoreceptors. However, the transform theory requires calculation of the exact geometries of not only the ground state but also the electronically excited states, which is time-consuming and requires extensive expertise in light of the many assumptions that need to be made.…”

Achievements in resonance Raman spectroscopy