Abstract
We present a photoelectron imaging study of the angular distributions in HO2− photodetachment. The transitions studied correspond to electron detachment from the a″ HOMO and a′ HOMO−1 of HO2−, yielding the neutral hydroperoxy radical in the ground and first excited electronic states. The experimental results are analysed using the p-d variant of the general model for photodetachment from mixed-character states. In this model, the parent anion molecular orbitals or the corresponding Dyson orbitals are described as superpositions of atomic p and d functions placed at a chosen centre in the molecular frame. As photoelectron angular distributions are sensitive to the long-range scaling of the parent orbitals, modelling the experimental results yields insight into the asymptotic behaviour of anionic wavefunctions. In the model, the long-range behaviour of diffuse orbitals is parameterised using the effective charges defining the basis functions. These parameters do not correspond to physical charges in the anion, but describe the long-range scaling of the p and d components of the model function and, therefore, the parent anion orbital. The experimental and model results for HO2− are compared to NO− and O2−, shedding light on the effects of molecular symmetry and chemical bonding structures on the photoelectron angular distributions.
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Acknowledgements
This work was made possible by funding from the U.S. National Science Foundation, Grant CHE-1664732. We thank Mikhail Ryazanov for his help with the circularization tool of the PyAbel program [Citation53]. Part of this work was conducted using the resources [Citation68] of the iOpenShell Center for Computational Studies of Electronic Structure and Spectroscopy of Open-Shell and Electronically Excited Species (http://iopenshell.usc.edu).
Disclosure statement
No potential conflict of interest was reported by the authors.