The effect of hydrogen bonding on protonation energies and ion pair formation

The hydrogen-bonded comple\es between CH3NHz and (CH-&NH with HCI have been studied by the ab initio molecular orbital method using the 4-31G basis set. Calculations show that the proton potential curve has a sm\_ele mmimum near to the mtrogen atom m both complevzs. This means that the proton has be

TIus study IS concerned wrth proton-trvnsfer photoreactrons III hydrogen-bonded complexes and the formatlon of Ionized forms of naphthols in the ground state, m the presence of crown ethers. It has been found that a loss m electroruc excltatton energy may occur during the proton transfer m the hydro

Computer simulations of a protonated, linear cluster of four hydrogen-bonded water molecules, (O4H9) +, are reported. The potential energy surface governing the motion of the nuclei was described with the polarization model of Stillinger and co-workers. The quantization of all the hydrogen nuclei wa

## Abstract Substituent effects on the hydrogen bond energies of Watson−Crick‐type base pairs, formed between a chemically modified nucleic acid base derivative and an unmodified one, were evaluated by ab initio molecular orbital theory. Different trends were observed in the relationship between th