Abstract
The performance of the Hartree–Fock method and the three density functionals B3LYP, PBE0, and
CAM-B3LYP is compared to results based on the coupled cluster singles and doubles model in
predictions of the solvatochromic effects on the vertical n¿* and ¿* electronic excitation
energies of acrolein. All electronic structure methods employed the same solvent model, which is
based on the combined quantum mechanics/molecular mechanics approach together with a
dynamical averaging scheme. In addition to the predicted solvatochromic effects, we have also
performed spectroscopic UV measurements of acrolein in vapor phase and aqueous solution. The
gas-to-aqueous solution shift of the n¿* excitation energy is well reproduced by using all density
functional methods considered. However, the B3LYP and PBE0 functionals completely fail to
describe the ¿* electronic transition in solution, whereas the recent CAM-B3LYP functional
performs well also in this case. The ¿* excitation energy of acrolein in water solution is found
to be very dependent on intermolecular induction and nonelectrostatic interactions. The computed
excitation energies of acrolein in vacuum and solution compare well to experimental data.
CAM-B3LYP is compared to results based on the coupled cluster singles and doubles model in
predictions of the solvatochromic effects on the vertical n¿* and ¿* electronic excitation
energies of acrolein. All electronic structure methods employed the same solvent model, which is
based on the combined quantum mechanics/molecular mechanics approach together with a
dynamical averaging scheme. In addition to the predicted solvatochromic effects, we have also
performed spectroscopic UV measurements of acrolein in vapor phase and aqueous solution. The
gas-to-aqueous solution shift of the n¿* excitation energy is well reproduced by using all density
functional methods considered. However, the B3LYP and PBE0 functionals completely fail to
describe the ¿* electronic transition in solution, whereas the recent CAM-B3LYP functional
performs well also in this case. The ¿* excitation energy of acrolein in water solution is found
to be very dependent on intermolecular induction and nonelectrostatic interactions. The computed
excitation energies of acrolein in vacuum and solution compare well to experimental data.
Originalsprog | Engelsk |
---|---|
Tidsskrift | Journal of Chemical Physics |
Vol/bind | 128 |
Sider (fra-til) | 194503-1 to 194503-15 |
Antal sider | 15 |
ISSN | 0021-9606 |
Status | Udgivet - 2008 |