Hydration of the hydronium ion: Ab initio calculations and monte carlo simulation

The energies of the hydrated I3r-ion for coordination numbers up to 4 hate been calculated with an ab initio hf0 method. The most favorable orientation is the ion-dipole one. in contrast to the H-bonded orientation for C17HaO) and F7HzO). The hydration energies cafcufa~ed in this study are in fair

## Recehd 15 Noxmber 1971 The energies of hydrated Iif, Na\*+, F-, 2nd Cl-ions ha.\= been calculated for coordination numbers up to 8. The resuits ofnb initio, ~c~li~rnpiljuf MO, and ciassinl methods are compared. The most probable, coordin3tioo numbers arid the corresponding orientation of the -x

The hydrarion enerpies for rhc NH: and CH3NH; ions wxc calculated by an ab initio MO method. The aqueous SCJ~KIlion cnrrgy diffcrencc bctwccn these IWO ions WCIS found to be accounted for by the interactions of the ions with a few sol-VClll 111111ecu1rs.

The conformation of the L-alanine zwitterion (ALAZ) in aqueous solution was examined by an ab initio MO method including the solvent effect with the generalized Born (GB) equation. The geometry optimization with the 6-31++G\* basis set gave the (, ) = (80, 8) conformation as the most stable conforma

Computer simulations of dilute aqueous solutions of Ca\*+ have been performed with a strictly two-body ab initio ion-water potential and an effective ab initio pair potential. The latter includes many-body effects in an average way relying on a continuum polarixable model for the solvent. With the t