Watson–Crick versus imidazopyridopyrimidine base pairs: theoretical study on differences in stability and hydrogen bonding strength

Evaluating interaction energy versus electron density relationships to estimate inter and intramolecular H-bonding

We investigate the computational effects on the relationships between interaction energy (ΔE) and electron density (ρ), at the critical point obtained from 19 intermolecular H-bonded dimers, to estimate inter and intramolecular interactions of larger H-bonded systems. Our analysis examines basis set superposition error (BSSE) effects, dispersion energy corrections, and the exchange-correlation energy model on the ΔE vs. ρ linear regressions. The calculations were carried out within density functional theory (DFT) combined with the 6-31+G(d,p) and def2-TZVPP basis sets. This procedure quantifies the average effects of BSSE for different levels of approximation, and underscore the sensitivity of the ΔE estimation together with dispersion corrections. This is valuable for the development of DFT-based estimators of multiple interaction energies of large H-bonded systems with low computational cost. We have applied this procedure by analyzing H-bonded biological molecules, such as DNA base pairs, an asparagine side chain, and an AZT molecule. Our estimated H-bond interaction energies are in agreement with previous studies, and emphasize the importance of methodological considerations for accurately predicting interaction energies using DFT combined with topological parameters.

Hydrogen bonding between hydrides of the upper-right part of the periodic table

One of the most important electrostatic interactions between molecules is most definitely the hydrogen bond. Understanding the basis of this interaction may offer us the insight needed to understand its effect on the macroscopic scale. Hydrogen bonding is for example the reason for anomalous properties in compounds like water and naturally life as we know it. The strength of the bond depends on numerous factors, among them the electronegativity of participating atoms. In this work we calculated the strength of hydrogen bonds between hydrides of the upper-right part of the periodic table (C, N, O, F, P, S, Cl, As, Se, Br) using quantum-chemical methods. The aim was to determine what influences the strength of strong and weak hydrogen bonds in simple hydrides. Various relationships were checked. A relation between the strength of the bond and the electronegativity of the participating atoms was found. We also observed a correlation between the strength of hydrogen bonds and the inter-atomic distances, along with the dependence on the charge transfer on the atom of the donor. We also report characteristic geometries of different dimers.