Vibrational modes in excited Rydberg states of acetone: A computational study

Computational studies of electronically excited states of the acetone molecule [(CH3)2CO] and its fully deuterated isotopologue [(CD3)2CO] are performed using the time dependent density functional (TDDFT) methodology. In addition to vertical excitation energies for singlet and triplet states, equili...

Full description

Saved in:
Bibliographic Details
Published inJournal of quantitative spectroscopy & radiative transfer Vol. 173; pp. 92 - 105
Main Authors Shastri, Aparna, Singh, Param Jeet
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.04.2016
Subjects
Online AccessGet full text

Cover

Loading…
More Information
Summary:Computational studies of electronically excited states of the acetone molecule [(CH3)2CO] and its fully deuterated isotopologue [(CD3)2CO] are performed using the time dependent density functional (TDDFT) methodology. In addition to vertical excitation energies for singlet and triplet states, equilibrium geometries and vibrational frequencies of the n=3 Rydberg states (3s, 3p and 3d) are obtained. This is the first report of geometry optimization and frequency calculations for the 3px, 3pz, 3dyz, 3dxy, 3dxz, 3dx2–y2 and 3dz2 Rydberg states. Results of the geometry optimization indicate that the molecule retains approximate C2V geometry in most of these excited Rydberg states, with the most significant structural change seen in the CCO bond angle which is found to be reduced from the ground state value. Detailed comparison of the computationally predicted vibrational wavenumbers with experimental studies helps to confirm several of the earlier vibronic assignments while leading to revised/new assignments for some of the bands. The important role of hot bands in analysis of the room temperature photoabsorption spectra of acetone is corroborated by this study. While the vibrational frequencies in excited Rydberg states are overall found to be close to those of the ionic ground state, geometry optimization and vibrational frequency computation for each excited state proves to be very useful to arrive at a consistent set of vibronic assignments. Isotopic substitution helps in consolidating and confirming assignments. An offshoot of this study is the interpretation of the band at ~8.47eV as the π–3s Rydberg transition converging to the second ionization potential. •TDDFT based computational studies of excited states of acetone-h6 and -d6.•Vertical excitation energies for singlet and triplet states.•Geometry optimization and vibrational frequencies of n=3 Rydberg states.•Comparison with experimental data; confirmation/revision of vibronic assignments.•Interpretation of the band at ~8.47eV as the π–3s Rydberg transition.
ISSN:0022-4073
1879-1352
DOI:10.1016/j.jqsrt.2016.01.011