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Experimentally Calibrated Analysis of the Electronic Structure of CuO + : Implications for Reactivity
Author(s) -
Srnec Martin,
Navrátil Rafael,
Andris Erik,
Jašík Juraj,
Roithová Jana
Publication year - 2018
Publication title -
angewandte chemie
Language(s) - English
Resource type - Journals
eISSN - 1521-3757
pISSN - 0044-8249
DOI - 10.1002/ange.201811362
Subject(s) - chemistry , copper , excited state , photodissociation , absorption spectroscopy , acetonitrile , electronic structure , photochemistry , reactivity (psychology) , ion , spectroscopy , neon , crystallography , computational chemistry , atomic physics , argon , physics , organic chemistry , medicine , alternative medicine , quantum mechanics , pathology
The CuO + core is a central motif of reactive intermediates in copper‐catalysed oxidations occurring in nature. The high reactivity of CuO + stems from a weak bonding between the atoms, which cannot be described by a simple classical model. To obtain the correct picture, we have investigated the acetonitrile‐ligated CuO + ion using neon‐tagging photodissociation spectroscopy at 5 K. The spectra feature complex vibronic absorption progressions in NIR and visible regions. Employing Franck–Condon analyses, we derived low‐lying triplet potential energy surfaces that were further correlated with multireference calculations. This provided insight into the ground and low‐lying excited electronic states of the CuO + unit and elucidated how these states are perturbed by the change in ligation. Thus, we show that the bare CuO + ion has prevailingly a copper(I)‐biradical oxygen character. Increasing the number of ligands coordinated to copper changes the CuO + character towards the copper(II)‐oxyl radical structure.