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1. Access to unsaturated bicyclic lactones by overriding conventional C(sp3)–H site selectivity

   https://doi.org/10.1038/s41557-023-01295-x  

   Das, Jayabrata; Ali, Wajid; Ghosh, Animesh; Pal, Tanay; Mandal, Astam; Teja, Chitrala; Dutta, Suparna; Pothikumar, Rajagopal; Ge, Haibo; Zhang, Xinglong; et al (November 2023, Nature Chemistry)

   Abstract Transition metal catalysis plays a pivotal role in transforming unreactive C–H bonds. However, regioselective activation of distal aliphatic C–H bonds poses a tremendous challenge, particularly in the absence of directing templates. Activation of a methylene C–H bond in the presence of methyl C–H is underexplored. Here we show activation of a methylene C–H bond in the presence of methyl C–H bonds to form unsaturated bicyclic lactones. The protocol allows the reversal of the general selectivity in aliphatic C–H bond activation. Computational studies suggest that reversible C–H activation is followed by β-hydride elimination to generate the Pd-coordinated cycloalkene that undergoes stereoselective C–O cyclization, and subsequent β-hydride elimination to provide bicyclic unsaturated lactones. The broad generality of this reaction has been highlighted via dehydrogenative lactonization of mid to macro ring containing acids along with the C–H olefination reaction with olefin and allyl alcohol. The method substantially simplifies the synthesis of important bicyclic lactones that are important features of natural products as well as pharmacoactive molecules. 

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2. Transition-metal-catalyzed decarbonylation of carboxylic acids to olefins: exploiting acyl C–O activation for the production of high value products

   https://doi.org/10.1039/C8QO00585K  

   Zhang, Xu; Jordan, Frank; Szostak, Michal (January 2018, Organic Chemistry Frontiers)

   Transition-metal-catalyzed decarbonylation reactions of aliphatic carboxylic acids produce olefins via one carbon degradation. Recently, tremendous progress has been made in the development of new protocols for the synthesis of linear olefins by the formal acyl C–O activation mechanism of ubiquitous carboxylic acids. Various transition metals including nickel, palladium, iridium and iron have been shown to catalyze the reaction and achieve excellent yields and selectivity. The use of new ligand systems has resulted in unprecedented control of selectivity of elementary steps in the catalytic cycle. The development of new acyl precursors expands the access to α-olefins and offers promising perspectives for applications in preparative organic synthesis. In this article, we highlight the recent noteworthy developments in the transition-metal-catalyzed decarbonylation of carboxylic acids and discuss future challenges in this field. 

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3. Ligand-enabled ortho -C–H olefination of phenylacetic amides with unactivated alkenes

   https://doi.org/10.1039/c7sc04827k  

   Lu, Ming-Zhu; Chen, Xing-Rong; Xu, Hui; Dai, Hui-Xiong; Yu, Jin-Quan (January 2018, Chemical Science)

   Although chelation-assisted C–H olefination has been intensely investigated, Pd( ii )-catalyzed C–H olefination reactions are largely restricted to acrylates and styrenes. Here we report a quinoline-derived ligand that enables the Pd( ii )-catalyzed olefination of the C(sp 2 )–H bond with simple aliphatic alkenes using a weakly coordinating monodentate amide auxiliary. Oxygen is used as the terminal oxidant with catalytic copper as the co-oxidant. A variety of functional groups in the aliphatic alkenes are tolerated. Upon hydrogenation, the ortho -alkylated product can be accessed. The utility of this reaction is also demonstrated by the late-stage diversification of drug molecules. 

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4. Synthesis and reactivity of (Pybox)Os and (Pybox)Ru complexes: Comparison with isoelectronic (Phebox)Ir complexes

   Parihar, Ashish; Malakar, Santanu; Emge, Thomas J; Goldman, Alan S (September 2022, American Chemical Society)

   Our laboratory has reported that (CX3Phebox)Ir(H)(OAc) (X = H, F) catalysts are highly active for the acceptorless dehydrogenation of n-alkanes1, particularly in the presence of Lewis acids. In this work we report the synthesis of isoelectronic (Pybox)Os(H)(OAc) and (Pybox)Ru(H)(OAc), and investigation of these complexes for alkane dehydrogenation. DFT calculations predict (Pybox)Ru(H)(OAc) to catalyze acceptorless alkane dehydrogenation with a barrier lower than that for (CH3Phebox)Ir(H)(OAc), while the barrier calculated for (Pybox)Os(H)(OAc) is even lower. The rate-limiting step chem. for the catalytic cycle is calculated to be a net M-H/C-H σ-bond metathesis reaction, although expulsion of H2 from the reaction mixture was found to be rate-determining under typical conditions for acceptorless n-alkane dehydrogenation catalyzed by (CF3Phebox)Ir(H)(OAc). H/D exchange experiments were used to probe the kinetics of C-H activation yielding the order of activity: (Pybox)Os(H)(OAc) > (Pybox)Ru(H)(OAc) > (CF3Phebox)Ir(H)(OAc). Exptl. investigation of catalysis by (Pybox)Ru(H)(OAc) and (Pybox)Os(H)(OAc) is still in progress but the Ru complex, unfortunately, does not appear to be stable at the high temperatures required for acceptorless alkane dehydrogenation. We have also reported that (CH3Phebox)Ir(C2H4)2 catalyzes selective dehydrogenative coupling of ethylene to butadiene via an iridacyclopentane complex.2 In this work we used the precursor (Pybox)OsH4 to investigate the same catalytic reaction and appears to result in and analogous dehydrogenative coupling of ethylene to form butadiene via an osmacyclopentane. 

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5. Scalable Electrochemical Decarboxylative Olefination Driven by Alternating Polarity**

   https://doi.org/10.1002/anie.202309157  

   Garrido‐Castro, Alberto F.; Hioki, Yuta; Kusumoto, Yoshifumi; Hayashi, Kyohei; Griffin, Jeremy; Harper, Kaid C.; Kawamata, Yu; Baran, Phil S. (September 2023, Angewandte Chemie International Edition)

   Abstract A mild, scalable (kg) metal‐free electrochemical decarboxylation of alkyl carboxylic acids to olefins is disclosed. Numerous applications are presented wherein this transformation can simplify alkene synthesis and provide alternative synthetic access to valuable olefins from simple carboxylic acid feedstocks. This robust method relies on alternating polarity to maintain the quality of the electrode surface and local pH, providing a deeper understanding of the Hofer‐Moest process with unprecedented chemoselectivity. 

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