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1. Light‐Driven Hydrodefluorination of Electron‐Rich Aryl Fluorides by an Anionic Rhodium‐Gallium Photoredox Catalyst

   https://doi.org/10.1002/anie.202205575  

   Moore, James T.; Dorantes, Michael J.; Pengmei, Zihan; Schwartz, Timothy M.; Schaffner, Jacob; Apps, Samantha L.; Gaggioli, Carlo A.; Das, Ujjal; Gagliardi, Laura; Blank, David A.; et al (September 2022, Angewandte Chemie International Edition)

   Abstract An anionic Rh−Ga complex catalyzed the hydrodefluorination of challenging C−F bonds in electron‐rich aryl fluorides and trifluoromethylarenes when irradiated with violet light in the presence of H₂, a stoichiometric alkoxide base, and a crown‐ether additive. Based on theoretical calculations, the lowest unoccupied molecular orbital (LUMO), which is delocalized across both the Rh and Ga atoms, becomes singly occupied upon excitation, thereby poising the Rh−Ga complex for photoinduced single‐electron transfer (SET). Stoichiometric and control reactions support that the C−F activation is mediated by the excited anionic Rh−Ga complex. After SET, the proposed neutral Rh⁰intermediate was detected by EPR spectroscopy, which matched the spectrum of an independently synthesized sample. Deuterium‐labeling studies corroborate the generation of aryl radicals during catalysis and their subsequent hydrogen‐atom abstraction from the THF solvent to generate the hydrodefluorinated arene products. Altogether, the combined experimental and theoretical data support an unconventional bimetallic excitation that achieves the activation of strong C−F bonds and uses H₂and base as the terminal reductant. 

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2. Traffic Lights for Catalysis: Stimuli‐Responsive Molecular and Extended Catalytic Systems

   https://doi.org/10.1002/anie.202302859  

   Thaggard, Grace_C; Haimerl, Johanna; Fischer, Roland_A; Park, Kyoung_Chul; Shustova, Natalia_B (April 2023, Angewandte Chemie International Edition)

   Abstract The advances made in the field of stimuli‐responsive catalysis during the last five years with a focus on the novel recently‐emerged directions and applications have been surveyed. Metal‐free catalysts and organometallic complexes, as well as biomimetic systems and extended structures, which display switchable catalytic activity for a variety of organic transformations, are discussed. Light‐activated systems comprised of photochromic molecules capable of modulating reaction rate, yield, or enantioselectivity based on geometric and electronic changes associated with photoisomerization are the focus of the detailed discussion. Alternative stimuli, including pH and temperature, which could be applied either alone or in combination with light, are also addressed. Recent advances clearly demonstrate that the capability to finely tune catalyst behavior via an external stimulus is a powerful tool that could alter the landscape of sustainable chemistry. 

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3. Aryl-, Akynyl-, and Alkenylbenziodoxoles: Synthesis and Synthetic Applications

   https://doi.org/10.3390/molecules28052136  

   Mironova, Irina A.; Noskov, Dmitrii M.; Yoshimura, Akira; Yusubov, Mekhman S.; Zhdankin, Viktor V. (March 2023, Molecules)

   Hypervalent iodine reagents are in high current demand due to their exceptional reactivity in oxidative transformations, as well as in diverse umpolung functionalization reactions. Cyclic hypervalent iodine compounds, known under the general name of benziodoxoles, possess improved thermal stability and synthetic versatility in comparison with their acyclic analogs. Aryl-, alkenyl-, and alkynylbenziodoxoles have recently received wide synthetic applications as efficient reagents for direct arylation, alkenylation, and alkynylation under mild reaction conditions, including transition metal-free conditions as well as photoredox and transition metal catalysis. Using these reagents, a plethora of valuable, hard-to-reach, and structurally diverse complex products can be synthesized by convenient procedures. The review covers the main aspects of the chemistry of benziodoxole-based aryl-, alkynyl-, and alkenyl- transfer reagents, including preparation and synthetic applications. 

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4. Enhanced activity of bulky N-heterocyclic carbenes in nickel–NHC catalyzed Kumada–Corriu cross-coupling of aryl tosylates

   https://doi.org/10.1039/D2CY01805E  

   Kardela, Marlena; Halikowska-Tarasek, Katarzyna; Szostak, Michal; Bisz, Elwira (December 2022, Catalysis Science & Technology)

   Over the last decades, advances in Ni catalysis have expanded the chemical reactivity of cross-coupling reactions and led to the discovery of catalytic systems that are now widely applied in industrial and academic research. Herein, we report the cross-coupling of aryl tosylates by Ni–NHC catalysis using bulky N-heterocyclic carbene ligands. A notable feature of this operationally-simple method is the combination of ‘fluoride effect’ to minimize homocoupling and bulky NHC ligands, such as IPr* and IPr* MeO , that enhance the activity of Ni in cross-coupling and prevent hydrolysis of sensitive oxygen electrophiles. A broad range of aryl and heteroaryl tosylates underwent cross-coupling with high efficiency. The finding that easily accessible, bulky NHCs with flexible CHPh 2 wingtips enhance the reactivity in Ni–NHC cross-coupling represents a powerful approach for catalysis. 

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5. Temperature-Dependent Spin-Driven Dimerization Determines the Ultrafast Dynamics of a Copper(II)-Bound Tripyrrindione Radical

   https://doi.org/10.1021/acs.jpclett.3c02726  

   Kumar, Anshu; Thompson, Benjamin; Gautam, Ritika; Tomat, Elisa; Huxter, Vanessa (December 2023, The Journal of Physical Chemistry Letters)

   Radicals and other open-shell molecules play a central role in chemical transformations and redox chemistry. While radicals are often highly reactive, stable radical systems are desirable for a range of potential applications, ranging from materials chemistry and catalysis to spintronics and quantum information. Here we investigate the ultrafast properties of a stable radical system with temperature-dependent spin-tunable properties. This radical complex, Cu(II) hexaethyl tripyrrin-1,14-dione, accommodates unpaired electrons localized on both the copper metal center and the tripyrrolic ligand. The unusual combination of two unpaired electrons and high stability in this radical molecule enable switchable temperature-dependent spin coupling. Two-dimensional electronic spectroscopy measurements of Cu(II) hexaethyl tripyrrin-1,14-dione were collected at room temperature and at 77 K. At room temperature, the molecules are present as monomers and have short picosecond lifetimes. At 77 K, the molecules are present in a dimer form mediated by ferromagnetic and antiferromagnetic coupling. This reversible spin-driven dimerization changes the optical properties of the system, generating long-lived excitonic states. 

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