Benchmarks for 0-0 transitions of aromatic organic molecules: DFT/B3LYP, ADC(2), CC2, SOS-CC2 and SCS-CC2 compared to high-resolution gas-phase data

Nina O. C. Winter1,a), Nora K. Graf1,b), Samuel Leutwyler2,c) and Christof Hättig1,d)
1 Lehrstuhl für Theoretische Chemie, Ruhr-Universität Bochum, D-44780 Bochum, Germany
2 Departement für Chemie und Biochemie, University of Bern, Freiestrasse 3, CH-3012 Bern, Switzerland

Phys. Chem. Chem. Phys. 15, 6623-6630 (2013). doi:10.1039/c2cp42694c
(Received 2 August 2012; accepted 11 October 2012; published online 19 October 2012)

In the present study a benchmark set of medium-sized and large aromatic organic molecules with 10-78 atoms is presented. For this test set 0-0 transition energies measured in supersonic jets are compared to those calculated with DFT and the B3LYP functional, ADC(2), CC2 and the spin-scaled CC2 variants SOS-CC2 and SCS-CC2. Geometries of the ground and excited states have been optimized with these methods in polarized triple zeta basis sets. Zero-point vibrational corrections have been calculated with the same methods and basis sets. In addition the energies have been corrected by single point calculations with a triple zeta basis augmented with diffuse functions, aug-cc-pVTZ. The deviations of the theoretical results from experimental electronic origins, which have all been measured in the gas phase with high-resolution techniques, were evaluated. The accuracy of SOS-CC2 is comparable to that of unscaled CC2, whereas ADC(2) has slightly larger errors. The lowest errors were found for SCS-CC2. All correlated wave function methods provide significantly better results than DFT with the B3LYP functional. The effects of the energy corrections from the augmented basis set and the method-consistent calculation of the zero-point vibrational corrections are small. With this benchmark set reliable reference data for 0-0 transition energies for larger organic chromophores are available that can be used to benchmark the accuracy of other quantum chemical methods such as new DFT functionals or semi-empirical methods for excitation energies and structures. This benchmark set augments present benchmark sets which include mainly smaller molecules.


a) Electronic mail: Nina.Winter@theochem.rub.de
b) Electronic mail: Nora.Graf@rub.de
b) Electronic mail: leutwyler@iac.unibe.ch
d) Electronic mail: christof.haettig@rub.de


View Article:     PDF   (access restricted to domain theochem.rub.de)


Back to the list of Publications by the Quantum Chemistry (Hättig) Group