An adiabatic model for calculating overtone spectra of dimers such as (H(2)O)(2).

The near-infrared and visible wavelength spectrum of the water dimer is considered to be the major contributor to the so-called water continuum at these wavelengths. However, theoretical models of this spectrum require the simultaneous treatment of both monomer and dimer excitations. A model for treating this problem is proposed which is based upon a Franck-Condon-like separation between the monomer and dimer vibrational motions. In this model, one of the monomers is treated as the chromophore and its absorption is assumed to be given by its, possibly perturbed, vibrational band intensity. The main computational issue is the treatment of separate monomer and dimer motions. Various approaches for obtaining dimer vibration-rotation tunnelling spectra that allow for monomer motion are explored. These approaches include ways of treating the adiabatic separation of dimer vibrational modes from monomer vibrational modes. We classify the adiabatic separation methods under four main approaches: namely fixed-geometry, free-monomer, perturbed-monomer and coupled-monomer methods. The latter being the most computationally expensive as the monomer wave functions are dependent on the dimer coordinates. For each of these approaches, expectation values over the full potential are calculated for the given monomer vibrational wave functions. Various full (named VAP 2pD in the text) and partial (VAP (+p)D) averaging techniques are outlined to calculate the vibrationally averaged, monomer state-dependent, dimer interaction potentials. The computational costs associated with application of these techniques to the water dimer are estimated and the prospects for full calculations based on this approach are assessed.

Homopairing possibilities of the DNA base thymine and the RNA base uracil: an ab initio density functional theory study.

All planar homopairings of the DNA base thymine and the RNA base uracil are reported for the first time in this study. Using the idea of binding sites discussed in our previous work (Kelly et al. J. Phys. Chem. B 2005, 109, 11933; J. Phys. Chem. B 2005, 109, 22045) and ab initio density functional theory, we predict and relax 10 thymine and 10 uracil homopairs. The stabilization energies of the homopairs vary from just below zero to -0.82 eV. The results on the pair geometry and energetics are compared with those available in the literature. The collected data on all planar thymine and uracil homopairs can be used to construct the thymine and uracil superstructures seen experimentally on various surfaces.

Homopairing possibilities of the DNA base adenine.

Using calculations based on the ab initio density functional theory, we for the first time report all possible planar DNA base adenine homodimers. Two density functionals and both localized and plane wave basis sets were used, and the results are compared with previous quantum chemical and semiempirical calculations available for a few pairs. We find that there are 21 possible planar adenine pairs with variable binding energies ranging from -0.03 to -0.86 eV. More stable pairs are associated with two strong hydrogen bonds formed between the monomers, while the least stable pairs are characterized by two or one relatively weak bonds. We find that stable hydrogen bonds can be characterized by the difference charge density that shows well-developed regions of alternating excess and depletion of the electron charge similar to a "kebab" structure. The presented detailed information on all planar adenine pairs can be utilized, for example, in considering possible adenine monolayers seen on various surfaces.

Homopairing possibilities of the DNA bases cytosine and guanine: an ab initio DFT study.

All the planar homopairings of cytosine and guanine are reported for the first time in this study. The idea of binding sites suggested for the simple case of adenine homopairs (J. Phys. Chem. B 2005, 109, 11933) is shown to be applicable to more complicated molecules binding to each other via multiple hydrogen bonds and can be considered as a general method for constructing hydrogen bonding structures. As an example we consider homopairs formed by DNA bases cytosine and guanine, suggesting that there may be 13 cytosine and 17 guanine homopairs. However, only 11 cytosine and 15 guanine homopairs remain after atomic relaxation performed using ab initio density functional theory. Most of the homopairs obtained have not been studied before. The homopairs have significant binding energies, varying from -0.19 to -1.12 eV, that are explained by multiple hydrogen bonds formed between monomers in the pairs, up to four hydrogen bonds in most energetically favorable cases. The detailed information on all guanine and cytosine planar homopairs contained in this work can be used to construct various cytosine and guanine superstructures observed on different surfaces.