Size-Dependent Hydrogen Bonds of Cluster Ions between Phenol Cation Radicals and Water Molecules: A Molecular Orbital Study
1998; American Chemical Society; Volume: 102; Issue: 21 Linguagem: Inglês
10.1021/jp980468c
ISSN1520-5215
Autores Tópico(s)Photochemistry and Electron Transfer Studies
ResumoThe molecular structures and vibrational frequencies of [C6H5OH−(H2O)n]•+ (n = 1−4) are studied by employing ab initio molecular orbital methods. Since the hydrogen bond between phenol cation radicals and water molecules is much stronger than that of the neutral phenol−water system, the position of the proton of phenol cation radicals depends on the number of water molecules in the clusters [C6H5OH−(H2O)n]•+. Although the stable structure of [C6H5OH−(H2O)n]•+ varies depending on the method used in the calculation, the result obtained with the B3LYP density functional method gives good agreement with the experimental IR spectra. The proton-nontransferred form is found to be most stable for n = 1 and n = 2 clusters. In the cases of n ≥ 3, the most stable structures are the proton-transferred form. There are two types of structures obtained for n = 3 clusters, where the branched form is more stable than the chained form. The optimized structures for n = 3 and n = 4 clusters show that the H3O+ moiety prefers to interact with the phenoxy radical and two water molecules.
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