Frontier orbital stability of nitroxyl organic radicals probed by means of inner shell resonantly enhanced valence band photoelectron spectroscopy

Totani, R.; Ljubić, Ivan; Ciavardini, A.; Grazioli, C.; Galdenzi, F.; de Simone, M.; Coreno, M. (2022) Frontier orbital stability of nitroxyl organic radicals probed by means of inner shell resonantly enhanced valence band photoelectron spectroscopy. Physical Chemistry Chemical Physics, 24 (4). pp. 1993-2003. ISSN 1463-9076

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Abstract

We have investigated the frontier orbitals of persistent organic radicals known as nitroxyls by resonant photoelectron spectroscopy (ResPES) under inner shell excitation. By means of this site-specific technique, we were able to disentangle the different atomic contributions to the outer valence molecular orbitals and examine several core–hole relaxation pathways involving the singly occupied molecular orbital (SOMO) localized on the nitroxyl group. To interpret the ResPES intensity trends, especially the strong enhancement of the SOMO ionized state at the N K-edge, we computed the Dyson spin orbitals (DSOs) pertaining to the transitions between the core-excited initial states and several of the singly ionized valence final states. We found that the computed vertical valence ionization potentials and norms of the DSOs are reasonably reliable when based on the long-range corrected CAM-B3LYP density functional. Thanks to their unpaired electrons, nitroxyls have recently found application in technological fields implying a spin control, such as spintronics and quantum computing. The present findings on the electronic structure of nitroxyl persistent radicals furnish important hints for their implementation in technological devices and, more in general, for the synthesis of new and stable organic radicals with tailored properties

Item Type:	Article
Uncontrolled Keywords:	resonantly enhanced valence band photoelectron spectroscopy; nitroxyl radicals; density functional theory; Dyson orbitals
Subjects:	NATURAL SCIENCES > Chemistry NATURAL SCIENCES > Chemistry > Physical Chemistry NATURAL SCIENCES > Chemistry > Theoretical Chemistry
Divisions:	Division of Physical Chemistry
Projects:	Project title Project leader Project code Project type Efekt kvantnog tuneliranja: dinamika molekula s kvantnim jezgrama-QuanTunMol Marko Tomislav Cvitaš IP-2020-02-9932 HRZZ
Depositing User:	Ivan Ljubić
Date Deposited:	13 Feb 2024 09:35
URI:	http://fulir.irb.hr/id/eprint/8554
DOI:	10.1039/d1cp05264k

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