A determination of Mg(+)-ligand binding energies
Abstract
Theoretical calculations employing large basis sets and including correlation are carried out for Mg(+) with methanol, water, and formaldehyde. For Mg(+) with ethanol and acetaldehyde, the trends in the binding energies are studied at the self-consistent-field level. The predictions for the binding energy of Mg(+) to methanol and water of 41 + or - 5 and 36 + or - 5 kcal/mol, respectively, are much less than the experimental upper bounds, of 61 + or - 5 and 60 + or - 5 kcal mol, determined by using photodissociation techniques. The theoretical results are inconsistent with the onset of Mg(+) production observed in the photodissociation experiments, as the smallest absorptions are calculated at about 80 kcal/mol for both Mg(+)-CH3OH and Mg(+)-H2O, and these transitions are to bound excited states. The binding energy for Mg(+) with formaldehyde is predicted to be similar to Mg(+)-H2O. The relative binding energies are in reasonable agreement with experiment. The binding energy of a second water molecule to Mg(+) is predicted to be similar to the first. This suggests that the reduced reaction rate observed for the second ligand is not a consequence of a significantly smaller binding energy, at least for the smaller ligards such as those considered in this work.
- Publication:
-
Journal of Physical Chemistry
- Pub Date:
- May 1991
- Bibcode:
- 1991JPhCh..95.3946B
- Keywords:
-
- Ligands;
- Magnesium;
- Metal Ions;
- Nuclear Binding Energy;
- Organometallic Compounds;
- Self Consistent Fields;
- Acetaldehyde;
- Ethyl Alcohol;
- Formaldehyde;
- Methyl Alcohol;
- Molecular Structure;
- Water;
- Atomic and Molecular Physics