1. The electronic structure and deexcitation pathways of an isolated metalloporphyrin ion resolved by metal L-edge spectroscopy
- Author
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Kaan Atak, Bernd von Issendorff, J. Tobias Lau, Xin Wang, Christine Bülow, S. Klumpp, Piter S. Miedema, Thomas Schlathölter, Sadia Bari, Simone Techert, Meiyuan Guo, Simon Dörner, Martin Timm, Lucas Schwob, Kaja Schubert, V. Zamudio-Bayer, and Quantum interactions and structural dynamics
- Subjects
Materials science ,Large scale facilities for research with photons neutrons and ions ,02 engineering and technology ,General Chemistry ,Electronic structure ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Photochemistry ,Antibonding molecular orbital ,01 natural sciences ,Metal L-edge ,0104 chemical sciences ,3. Good health ,Ion ,Dication ,Chemistry ,ddc:540 ,Mass spectrum ,Molecular orbital ,0210 nano-technology ,Ground state - Abstract
The local electronic structure of the metal-active site and the deexcitation pathways of metalloporphyrins are crucial for numerous applications but difficult to access by commonly employed techniques. Here, we applied near-edge X-ray absorption mass spectrometry and quantum-mechanical restricted active space calculations to investigate the electronic structure of the metal-active site of the isolated cobalt(iii) protoporphyrin IX cation (CoPPIX+) and its deexcitation pathways upon resonant absorption at the cobalt L-edge. The experiments were carried out in the gas phase, thus allowing for control over the chemical state and molecular environment of the metalloporphyrin. The obtained mass spectra reveal that resonant excitations of CoPPIX+ at the cobalt L3-edge lead predominantly to the formation of the intact radical dication and doubly charged fragments through losses of charged and neutral side chains from the macrocycle. The comparison between experiment and theory shows that CoPPIX+ is in a 3A2g triplet ground state and that competing excitations to metal-centred non-bonding and antibonding σ* molecular orbitals lead to distinct deexcitation pathways., Near-edge X-ray absorption mass spectrometry (NEXAMS) and restricted active space (RAS) quantum mechanical calculations at the metal L-edge reveal the electronic structure and orbital-specific deexcitation pathways of gas-phase metalloporphyrins.
- Published
- 2021
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