Binding Energies for Successive Addition Reaction of .OH with C60 : A Laboratory for Testing Frontier Molecular Orbital Theory

• Published in: arXiv.org
• Main Authors: Ponra, Abraham, Etindele, Anne Justine, Motapon, Ousmanou, Casida, Mark Eurl
• Format: Paper
• Language: English
• Published: Ithaca Cornell University Library, arXiv.org 20.12.2022
• Subjects: Buckminsterfullerene; Density functional theory; Fullerenes; Hydroxyl groups; Mathematical analysis; Molecular orbitals; Radicals; Regioselectivity; Stability analysis
• ISSN: 2331-8422

We study the successive addition reaction of .OH on fullerene C60. We confirm that the lowest energy isomers of C60(OH)n form a belt of hydroxyl groups around the equator of C60, but ask the question of what governs the relative stability of subtitutions at different carbons? Factors concerning regioselectivity are analyzed in terms of conceptual density-functional theory, frontier molecular orbital theory, charge and spin densities, based upon Mulliken population analysis. We confirm that .OH is an electrophilic radical whose successive reaction with C60 is under both charge and orbital control. This is seen to be especially the case for addition to odd .C60(OH)2m+1 fullerenols, but is also seen from a Fukui function and dual descriptor analysis for even C60(OH)2m fullerenols. Of particular interest is the ability of the condensed radical Fukui function f0 to provide information about the reactivity of even C60(OH)2m fullerenols with .OH also when the spin density is zero, and the observation that the interpretation of the sign of the dual descriptor changes depending upon whether a spin-restricted calculation is being performed for even C60(OH)2m fullerenols or a spin-unrestricted calculation is being performed for odd .C60(OH)2m+1 fullerenols.