Infrared Spectroelectrochemistry of Iron-Nitrosyl Triarylcorroles. Implications for Ligand Noninnocence
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https://hdl.handle.net/10037/24835Date
2020-02-13Type
Journal articleTidsskriftartikkel
Peer reviewed
Abstract
Recent DFT calculations have suggested that iron nitrosyl triarylcorrole
complexes have substantial {FeNO}7
−corrole•2− character. With this formulation, reduction
of Fe(C)(NO) complexes, where C = triarylcorrole, should be centered on the corrole
macrocycle rather than on the {FeNO}7 moiety. To verify this proposition, visible and
infrared spectroelectrochemical studies of Fe(C)(NO) were carried out and the results were
interpreted using DFT (B3LYP/STO-TZP) calculations. The first reduction of Fe(C)(NO)
led to significant changes in the Soret and Q-band regions of the visible spectrum as well as to
a significant downshift in the νNO and changes in the corrole vibrational frequencies. DFT
calculations, which showed that the electron was mostly added to the corrole ligand (85%),
were also able to predict the observed shifts in the νNO and corrole bands upon reduction. These results underscore the importance
of monitoring both the corrole and nitrosyl vibrations in ascertaining the site of reduction. By contrast, the visible
spectroelectrochemistry of the second reduction revealed only minor changes in the Soret band upon reduction, consistent with
the reduction of the FeNO moiety.
Publisher
American chemical societyCitation
Rahman, Ryan, Vazquez-Lima H, Alemayehu A, Ghosh A. Infrared Spectroelectrochemistry of Iron-Nitrosyl Triarylcorroles. Implications for Ligand Noninnocence. Inorganic Chemistry. 2020;59:3232-3238Metadata
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