Quantum chemical study of the π-electronic states of the DNA base pairs

The relative energies of the energetically low-lying tautomers of pyridone, cytosine, uracil, thymine, guanine, and iso-cytosine are studied by a variety of different quantum chemical methods. In particular, we employ density functional theory (DFT) using the six functionals HCTH407, PBE, BP86, B-LY

The lower-lying singlet and triplet states of o-benzyne (C,H,) have been calculated by ab initio methods such as CASSCF, CASPTZ, MR-CISD and MR-ACPF schemes employing an AN0 basis set as well as the CIS method. The calculated results are compared with a recent electronic absorption spectrum of trans

## Abstract The nature of the base pairing between cytosine and 2‐aminopurine is investigated by means of quantum mechanical calculations including electron correlation and accounting for the effects of aqueous solvation. At neutral pH, both a neutral wobble base pair and a Watson–Crick‐like base p

Ab-initio pseudopotential and all-electron SCF calculations of the molecules ArF6. KrF6, XeF6 and the isoelectronic ions ClFs. BrF6-. IFe-have been performed with the TURBOMOLE and the GAUSSIAN90 programs. Geometry optimisation in Cj, symmetry leads for XeF6 to a distorted structure, for KrF6 to a

## Abstract The intermolecular electronic correlation contributions to the Coulomb component of the nucleic acid base interaction energy are estimated. The Coulomb energy is evaluated with the use of atomic monopoles, which are determined from the π‐electronic densities calculated by the SCF method