Abstract
Ground- and excited-state calculations of the triplet O2·NH3·nH2O complex as a model for solution photo-oxygenation of amines by triplet oxygen are reported at the AM1 and PM3 SCF–MO levels. For n < 3, the first excited AM1 triplet state corresponds to local excitation on the ammonia (TN), whereas the polar excited state (TP) corresponding to NH3+·O2–· becomes the lowest excited triplet state when n≥ 3. In contrast, the lowest excited PM3 triplet state is ionic even for n= 0, and the TP and ground-state (T0) triplet surfaces intersect at an N–O distance of 1.95 A for n= 5, with TP becoming a local minimum on ground triplet state surface at shorter N–O distances. The reliability of these models are discussed in terms of known errors and properties of the AM1 and PM3 methods, and by a comparison of the solvation enthalpies and structures of systems such as NH4+·nH2O, NH4+·nNH3, and HO–·nH2O (n= 1–4) with known experimental values.
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