Direct Determination of a Giant Zero-Field Splitting of 5422 cm–1 in a Triplet Organobismuthinidene by Infrared Electron Paramagnetic Resonance

Tarek Al Said; Davide Spinnato; K. Holldack; Frank Neese; Josep Cornellà; Alexander Schnegg

doi:10.1021/jacs.4c14795

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Direct Determination of a Giant Zero-Field Splitting of 5422 cm–1 in a Triplet Organobismuthinidene by Infrared Electron Paramagnetic Resonance

Journal of the American Chemical Society

Article 2024 English

Abstract

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Stable monocoordinated organobismuthinidenes were only recently isolated and analyzed toward their chemical and electronic structure. Quantum chemical calculations on tBu-MSFluind-Bi(I) (2) predicted an unusual electronic structure dominated by a triplet ground state and a spectacular zero-field splitting (ZFS) > 4500 cm–1. However, experimental evidence for these predictions remained elusive due to limitations in the available magnetic characterization techniques. Herein, we determine an axial ZFS of D = 5422 cm–1 for 2, by direct detection of triplet electron paramagnetic resonance using magneto-optical infrared spectroscopy. To date, this represents the largest ZFS experimentally measured.

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Direct Determination of a Giant Zero-Field Splitting of 5422 cm<sup>–1</sup> in a Triplet Organobismuthinidene by Infrared Electron Paramagnetic Resonance

Abstract

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