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1. Identification of key functionalization species in the Cp*Ir( iii )-catalyzed- ortho halogenation of benzamides

   https://doi.org/10.1039/d0dt00565g  

   Guzmán Santiago, Alexis J.; Brown, Caleb A.; Sommer, Roger D.; Ison, Elon A. (January 2020, Dalton Transactions)

   Cp*Ir( iii ) complexes have been shown to be effective for the halogenation of N , N -diisopropylbenzamides with N -halosuccinimide as a suitable halogen source. The optimized conditions for the iodination reaction consist of 0.5 mol% [Cp*IrCl 2 ] 2 in 1,2-dichloroethane at 60 °C for 1 h to form a variety of iodinated benzamides in high yields. Increasing the catalyst loading to 6 mol% and the time to 4 h enabled the bromination reaction of the same substrates. Reactivity was not observed for the chlorination of these substrates. A variety of functional groups on the para -position of the benzamide were well tolerated. Kinetic studies showed the reaction dependence is first order in iridium, positive order in benzamide, and zero order in N -iodosuccinimide. A KIE of 2.5 was obtained from an independent H/D kinetic isotope effect study. Computational studies (DFT-BP3PW91) indicate that a CMD mechanism is more likely than an oxidative addition pathway for the C–H bond activation step. The calculated functionalization step involves an Ir( v ) species that is the result of oxidative addition of acetate hypoiodite that is generated in situ from N -iodosuccinimide and acetic acid. 

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2. Dehydrogenative Conversions of Aldehydes and Amines to Amides Catalyzed by a Nickel(II) Pincer Complex

   https://doi.org/10.3390/catal13111423  

   Szwedo, Peter; Jumper, Travis; Sanford, Karie; Arnold, Taylor; Coffman, Sarah; Hokes, Davonte; Munshi, Pradip; Walker, Brian; Ghosh, Anindya (November 2023, Catalysts)

   A C-N cross-coupling approach involving oxidative amidations of aromatic aldehydes in the presence of an amide-based nickel(II) pincer catalyst (2) is demonstrated. Upon optimization, quick reaction times (15 min) and an ideal temperature (25 °C) were established and implemented for the conversion of 33 different amide products using only 0.2 mol% of catalyst. Moderate to good turnover numbers (TONs) were obtained for secondary benzamide products, and moderate TONs were obtained for tertiary benzamide products, with the highest turnover number calculated for the 4-chloro-N-(3-phenylpropyl)benzamide product (4i, 309). Gas chromatographic–mass spectrometric (GC–MS) analysis also indicates the formation of alcohols in different reactions, indicating an oxidative amidation process. Kinetic studies were performed by varying the amount of catalyst, aldehyde, LiHMDS base, and amine substrate to determine the order of reaction for each component. Benzaldehyde and benzaldehyde-d6 were reacted with benzylamine, and the kH/kD ratio was determined to understand the rate-determining step. Isotope labeling further revealed that deuterium was being transferred to both the alcohol side product and the target amide product. With the help of kinetic data and UV–visible spectra, a mechanism for the amidation process via the catalyst (2) is proposed through a Ni(I)–Ni(III) pathway. 

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3. Palladium-catalyzed decarbonylative Suzuki–Miyaura cross-coupling of amides by carbon–nitrogen bond activation

   https://doi.org/10.1039/c9sc03169c  

   Zhou, Tongliang; Ji, Chong-Lei; Hong, Xin; Szostak, Michal (October 2019, Chemical Science)

   Palladium-catalyzed Suzuki–Miyaura cross-coupling or aryl halides is widely employed in the synthesis of many important molecules in synthetic chemistry, including pharmaceuticals, polymers and functional materials. Herein, we disclose the first palladium-catalyzed decarbonylative Suzuki–Miyaura cross-coupling of amides for the synthesis of biaryls through the selective activation of the N–C(O) bond of amides. This new method relies on the precise sequence engineering of the catalytic cycle, wherein decarbonylation occurs prior to the transmetallation step. The reaction is compatible with a wide range of boronic acids and amides, providing valuable biaryls in high yields (>60 examples). DFT studies support a mechanism involving oxidative addition, decarbonylation and transmetallation and provide insight into high N–C(O) bond activation selectivity. Most crucially, the reaction establishes the use of palladium catalysis in the biaryl Suzuki–Miyaura cross-coupling of the amide bond and should enable the design of a wide variety of cross-coupling methods in which palladium rivals the traditional biaryl synthesis from aryl halides and pseudohalides. 

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4. Ruthenium(0)-catalyzed cross-coupling of aryl methyl ethers with organoboranes by selective C–O cleavage

   https://doi.org/10.1039/D3QO00042G  

   Zhang, Jin; Wang, Xin; Liu, Jiale; Wang, Xiaogang; Yang, Xinkan; Zhao, Qun; Ma, Yangmin; Fang, Ran; Szostak, Michal (March 2023, Organic Chemistry Frontiers)

   The activation of C–O bonds in aryl methyl ethers is a fundamental method for the cross-coupling of carbon–oxygen bonds; however, this process is highly challenging due to the high dissociation energy compared with other phenol derivatives. Herein, we report a mild Ru(0)-catalyzed cleavage of C(aryl)–O bonds enabled by a combination of a Ru 3 (CO) 12 catalyst and an imine auxiliary. This method offers rapid entry to synthetically valuable biaryl aldehydes from abundant anisoles. Broad functional group tolerance is observed using this strategy, including unprecedented tolerance towards aryl bromides. The synthetic utility of this strategy has been demonstrated in sequential processes to construct complex biaryls, exploiting the orthogonal selectivity of C–O bond activation. DFT studies were conducted to provide insight into the selectivity of C–O bond cleavage. This method establishes the mildest approach to C–OMe cross-coupling reported to date. 

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5. Nitrene C−H Bond Insertion Approach to Carbazolones and Indolones, and a Reactivity Departure for 7‐Membered Analogues**

   https://doi.org/10.1002/chem.202302995  

   Lakshman, Mahesh_K; Sebastian, Dellamol; Pradhan, Padmanava; Neary, Michelle_C; Piette, Alexis_M; Trzebiatowski, Samuel_P; Henriques, Alexander_E_K; Willoughby, Patrick_H (November 2023, Chemistry – A European Journal)

   Abstract A modular platform for facile access to 1,2,3,9‐tetrahydro‐4H‐carbazol‐4‐ones (H₄‐carbazolones) and 3,4‐dihydrocyclopenta[b]indol‐1(2H)‐ones (H₂‐indolones) is described. The requisite 6‐ and 5‐membered 2‐arylcycloalkane‐1,3‐dione precursors were readily obtained through a Cu‐catalyzed arylation of 1,3‐cyclohexanediones or by a ring expansion of aryl succinoin derivatives. Enolization of one carbonyl group in the diones, conversion to a leaving group, and subsequent azidation gave 2‐aryl‐3‐azidocycloalk‐2‐en‐1‐ones. This two‐step, one‐pot azidation is highly regioselective with unsymmetrically substituted 2‐arylcyclohexane‐1,3‐diones. The regioselectivity, which is important for access to single isomers of 3,3‐disubstituted carbazolones, was analyzed mechanistically and computationally. Finally, a Rh‐catalyzed nitrene/nitrenoid insertion into theorthoC−H bond of the aryl moiety gave the H₄‐carbazolones and H₂‐indolones. One carbazolone was elaborated to an intermediate reported in the total synthesis ofN‐decarbomethoxychanofruticosinate, (−)‐aspidospermidine, (+)‐kopsihainanine A. With 2‐phenylcycloheptane‐1,3‐dione, prepared from cyclohexanone and benzaldehyde, the azidation reaction was readily accomplished. However, the Rh‐catalyzed reaction unexpectedly led to a labile but characterizable azirine rather than the indole derivative. Computations were performed to understand the differences in reactivities of the 5‐ and 6‐membered 2‐aryl‐3‐azidocycloalk‐2‐en‐1‐ones in comparison to the 7‐membered analogue, and to support the structural assignment of the azirine. 

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