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1. Palladium‐Catalyzed Benzylic C(sp 3 )−H Carbonylative Arylation with Aryl Bromides

   https://doi.org/10.1002/ange.202300073  

   Hu, Bowen ; Zhao, Haoqiang ; Wu, Yu ; Walsh, Patrick J. ( April 2023 , Angewandte Chemie)

   A novel, selective and high‐yielding palladium‐catalyzed carbonylative arylation of a variety of weakly acidic (pK_a25–35 in DMSO) benzylic and heterobenzylic C(sp³)−H bonds with aryl bromides has been achieved. This system is applicable to a range of pro‐nucleophiles for access to sterically and electronically diverse α‐aryl or α,α‐diaryl ketones, which are ubiquitous substructures in biologically active compounds. The Josiphos SL‐J001‐1‐based palladium catalyst was identified as the most efficient and selective, enabling carbonylative arylation with aryl bromides under 1 atm CO to provide the ketone products without the formation of direct coupling byproducts. Additionally, (Josiphos)Pd(CO)₂was identified as the catalyst resting state. A kinetic study suggests that the oxidative addition of aryl bromides is the turnover‐limiting step. Key catalytic intermediates were also isolated.

    

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2. Palladium‐Catalyzed Benzylic C(sp 3 )−H Carbonylative Arylation with Aryl Bromides

   https://doi.org/10.1002/anie.202300073  

   Hu, Bowen ; Zhao, Haoqiang ; Wu, Yu ; Walsh, Patrick J. ( April 2023 , Angewandte Chemie International Edition)

   A novel, selective and high‐yielding palladium‐catalyzed carbonylative arylation of a variety of weakly acidic (pK_a25–35 in DMSO) benzylic and heterobenzylic C(sp³)−H bonds with aryl bromides has been achieved. This system is applicable to a range of pro‐nucleophiles for access to sterically and electronically diverse α‐aryl or α,α‐diaryl ketones, which are ubiquitous substructures in biologically active compounds. The Josiphos SL‐J001‐1‐based palladium catalyst was identified as the most efficient and selective, enabling carbonylative arylation with aryl bromides under 1 atm CO to provide the ketone products without the formation of direct coupling byproducts. Additionally, (Josiphos)Pd(CO)₂was identified as the catalyst resting state. A kinetic study suggests that the oxidative addition of aryl bromides is the turnover‐limiting step. Key catalytic intermediates were also isolated.

    

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3. Synthesis of Diarylated 4‐Pyridylmethyl Ethers via Palladium‐Catalyzed Cross‐Coupling Reactions

   https://doi.org/10.1002/adsc.201700380  

   Ablajan, Keyume ; Panetti, Grace B. ; Yang, Xiaodong ; Kim, Byeong‐Seon ; Walsh, Patrick J. ( May 2017 , Advanced Synthesis & Catalysis)

   The direct arylation of weakly acidicsp³‐hybridized C–H bondsviadeprotonated cross‐coupling processes (DCCP) is a challenge. Herein, a palladium(NIXANTPHOS)‐based catalyst for the monoarylation of 4‐pyridylmethyl 2‐aryl ethers to generate diarylated 4‐pyridyl methyl ethers is introduced. Furthermore, under similar conditions, the diarylation of 4‐pyridyl methyl ethers with aryl bromides has been developed. These methods enable the synthesis of new pyridine derivatives, which are common in medicinally active compounds and have applications in materials science.

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4. Palladium‐Catalyzed Carbonylative Cross‐Coupling of Aryl Iodides and Alkenyl Bromides with Benzyl Halides under Reductive Conditions

   https://doi.org/10.1002/ajoc.202200243  

   Lin, Tingzhi ; Qian, Pengcheng ; Wang, Yan‐En ; Ou, Mingjie ; Cui, Ning ; Ye, Yu ; Hua, Rui ; Xiong, Dan ; Xue, Fei ; Walsh, Patrick J. ; et al ( November 2022 , Asian Journal of Organic Chemistry)

   A direct and convenient method for the palladium‐catalyzed reductive cross‐coupling of aryl iodides or alkenyl bromides and secondary benzyl halides under ambient CO pressure to generate a diverse array of aryl/alkenyl alkyl ketones has been developed. This strategy successfully achieves a three‐component carbonylative reaction with Zn as the reducing agent for C−C bond formation, overcoming the well‐known homocoupling of aryl or alkenyl halides, direct cross‐coupling between two different electrophiles and other carbonylative coupling reactions. In addition, this method avoids use of preformed organometallic nucleophiles, such as organo‐magnesium, zinc and boron reagents. This approach enables the construction of valuable aryl alkyl/alkenyl ketone derivatives (60 examples, 56–95% yields). Reactivity studies indicate that in situ formed benzylic zinc reagents are intermediates in the catalytic system.

    

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5. Transition-metal-free C(sp 3 )–H/C(sp 3 )–H dehydrogenative coupling of saturated heterocycles with N -benzyl imines

   https://doi.org/10.1039/D0SC00031K  

   Liu, Zhengfen ; Li, Minyan ; Deng, Guogang ; Wei, Wanshi ; Feng, Ping ; Zi, Quanxing ; Li, Tiantian ; Zhang, Hongbin ; Yang, Xiaodong ; Walsh, Patrick J. ( January 2020 , Chemical Science)

   A unique C(sp 3 )–H/C(sp 3 )–H dehydrocoupling of N -benzylimines with saturated heterocycles is described. Using super electron donor (SED) 2-azaallyl anions and aryl iodides as electron acceptors, single-electron-transfer (SET) generates an aryl radical. Hydrogen atom transfer (HAT) from saturated heterocycles or toluenes to the aryl radical generates alkyl radicals or benzylic radicals, respectively. The newly formed alkyl radicals and benzylic radicals couple with the 2-azaallyl radicals with formation of new C–C bonds. Experimental evidence supports the key hydrogen-abstraction by the aryl radical, which determines the chemoselectivity of the radical–radical coupling reaction. It is noteworthy that this procedure avoids the use of traditional strong oxidants and transition metals. 

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