Light Activation and Photophysics of a Structurally Constrained Nickel(II)–Bipyridine Aryl Halide Complex
Abstract
Transition-metal photoredox catalysis has transformed organic synthesis by harnessing light to construct complex molecules. Nickel(II)–bipyridine (bpy) aryl halide complexes are a significant class of cross-coupling catalysts that can be activated via direct light excitation. This study investigates the effects of molecular structure on the photophysics of these catalysts by considering an underexplored, structurally constrained Ni(II)–bpy aryl halide complex in which the aryl and bpy ligands are covalently tethered alongside traditional unconstrained complexes. Intriguingly, the tethered complex is photochemically stable but features a reversible Ni(II)–C(aryl) ⇄ [Ni(I)···C(aryl)•] equilibrium upon direct photoexcitation. When an electrophile is introduced during photoirradiation, we demonstrate a preference for photodissociation over recombination, rendering the parent Ni(II) complex a stable source of a reactive Ni(I) intermediate. Here, we characterize the reversible photochemical behavior of the tethered complex by kinetic analyses, quantum chemical calculations, and ultrafast transient absorption spectroscopy. Comparison to the previously characterized Ni(II)–bpy aryl halide complex indicates that the structural constraints considered here dramatically influence the excited state relaxation pathway and provide insight into the characteristics of excited-state Ni(II)–C bond homolysis and aryl radical reassociation dynamics. This study enriches the understanding of molecular structure effects in photoredox catalysis and offers new possibilities for designing customized photoactive catalysts for precise organic synthesis.
Copyright and License
© 2024 American Chemical Society.
Acknowledgement
We acknowledge Dr. Erica Sutcliffe and Nathanael P. Kazmierczak for helpful discussions. This project has received funding from the European Union’s Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement no. 883987 (D.B.). K.M.L. and D.A.C. acknowledge support from the National Science Foundation Graduate Research Fellowship (NSF GRFP) under grant no. DGE-1745301. Support has been provided by the National Institutes of Health (National Institute of General Medical Sciences, R35-GM142595). The computations presented here were in part conducted in the Resnick High Performance Computing Center, a facility supported by Resnick Sustainability Institute at the California Institute of Technology and in part by the IT4Innovations National Supercomputing Center under the programme of the Ministry of Education, Youth and Sports of the Czech Republic through the e-INFRA CZ (ID:90254).
Contributions
D.B.: conceptualization; methodology; investigation; formal analysis; writing─original draft; writing─review and editing. K.M.L.: methodology; investigation; formal analysis; writing─original draft; writing─review and editing. D.A.C.: methodology; writing─review and editing. R.G.H.: conceptualization; methodology; writing─original draft; writing─review and editing; supervision; project administration; funding acquisition.
Conflict of Interest
The authors declare no competing financial interest.
Data Availability
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Experimental and computational methods, synthetic details, UV–vis/photochemical data, kinetic modeling, transient absorption spectra analysis, NMR spectra, calculated properties, XYZ of the optimized structures, and additional comments (PDF)
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Additional details
- ISSN
- 1520-510X
- DOI
- 10.1021/acs.inorgchem.3c03822
- PMCID
- PMC11000520
- European Research Council
- Marie Skłowdoska-Curie Fellowship 883987
- National Science Foundation
- NSF Graduate Research Fellowship DGE-1745301
- National Institutes of Health
- R35-GM142595
- Ministry of Education Youth and Sports
- 90254
- Caltech groups
- Resnick Sustainability Institute