In recent years, low-valent chemical species such as radicals and carbenes, which have been recognized as short-lived intermediates, have been isolated by appropriate molecular design, and their chemical properties have been investigated in detail experimentally. In particular, the discovery of isolable carbenes, which are now widely used as indispensable ligands in coordination chemistry and synthetic organic chemistry, has enabled the development of novel highly active catalysts.
@article{abe2021new,title={New Insights into Bond Homolysis Process and Discovery of Novel Bonding System (C–π–C) by Generating Long-lived Singlet Diradicals},author={Abe, M. and Wang, Z. and Akisaka, R.},journal={AsiaChem},volume={2},issue={1},pages={32--41},year={2021},month=dec,publisher={ics},doi={10.51167/acm00020.51167/acm00021},url={https://doi.org/10.51167/acm00020.51167/acm00021},dimensions={true},tab={review}}
Review
Singly Occupied Molecular Orbital−Highest Occupied Molecular Orbital (SOMO−HOMO) Conversion
Singly occupied molecular orbital−highest occupied molecular orbital (SOMO−HOMO) conversion (inversion), SHC, is a phenomenon in which the SOMO is lower in energy than the doubly occupied molecular orbitals (DOMO, HOMO). A non-Aufbau electronic structure leads to unique properties such as a switch in bond dissociation energy and the generation of high-spin species on one-electron oxidation. In addition, the pronounced photostability of these species has been reported recently for application in organic light-emitting devices. In this review article, we summarise the chemistry of SOMO−HOMO converted (inverted) species reported to date.
@article{murata2021singly,title={Singly Occupied Molecular Orbital−Highest Occupied Molecular Orbital (SOMO−HOMO) Conversion},author={Murata, R. and Wang, Z. and Abe, M.},journal={Aust. J. Chem.},volume={74},issue={12},pages={827--837},year={2021},month=oct,publisher={csiro},doi={10.1071/ch21186},url={https://doi.org/10.1071/ch21186},dimensions={true},tab={review}}
Review
Long-lived localised singlet diradicaloids with carbon–carbon π-single bonding (C–π–C)
Localised singlet cyclopentane-1,3-diyl diradicaloids have been considered promising candidates for constructing carbon–carbon π-single bonds (C–π–C). However, the high reactivity during formation of the σ-bond has limited a deeper investigation of its unique chemical properties. In this feature article, recent progress in kinetic stabilisation based on the “stretch effect” and the “solvent dynamic effect” induced by the macrocyclic system is summarised. Singlet diradicaloids S-DR4a/b and S-DR4d containing macrocyclic rings showed much longer lifetimes at 293 K (14 μs for S-DR4a and 156 μs for S-DR4b in benzene) compared to the parent singlet diradicaloid S-DR2 having no macrocyclic ring (209 ns in benzene). Furthermore, the dynamic solvent effect in viscous solvents was observed for the first time in intramolecular σ-bond formation, the lifetime of S-DR4d increased to 400 μs in the viscous solvent glycerin triacetin at 293 K. The experimental results proved the validity of the “stretch effect” and the “solvent dynamic effect” on the kinetic stabilisation of singlet cyclopentane-1,3-diyl diradicaloids, and provided a strategy for isolating the carbon–carbon π-single bonded species (C–π–C), and towards a deeper understanding of the nature of chemical bonding.
@article{wang2021long,title={Long-lived localised singlet diradicaloids with carbon–carbon π-single bonding (C–π–C)},author={Wang, Z. and Yadav, P. and Abe, M.},journal={Chem. Commun.},volume={57},issue={86},pages={11301--11309},year={2021},month=sep,publisher={rsc},doi={10.1039/d1cc04581d},url={https://doi.org/10.1039/d1cc04581d},dimensions={true},tab={review}}
