The selective addition reaction of unsaturated C-C bonds has always been a classic and constant research topic.Different from well-developed hydroboration,hydrosilylation,and hydrostannylation reaction,hydrogermylatio...The selective addition reaction of unsaturated C-C bonds has always been a classic and constant research topic.Different from well-developed hydroboration,hydrosilylation,and hydrostannylation reaction,hydrogermylation reaction remains challenging which hasn't been much reported.Herein,we developed a new metal-porous ligand polymers Pd1@POL-PPh_(n)Cy_(m)(n+m=3)with monoatomic dispersion characteristics for highly selective and efficient hydrogermylation of unsaturated C-C bonds,including alkynes,alkenes,and allenes.X-ray photoelectron spectroscopy and theoretical calculations further proved the introduction of cyclohexyl could gently adjust the charge on monoatomic Pd center which effectively facilitate the recognition and transformation of various substrates.With the electrically fine-tuned single atom palladium catalysts,we realized theα-germanium addition for the first time,obtaining corresponding allyl germanium and alkyl germanium compounds.展开更多
An efficient and scalable electrochemical asymmetric protocol with metal-free catalysts and even without additional oxidants for the cross-dehydrogenative coupling reaction(CDC)of two C(sp^(3))-H bonds is reported.A s...An efficient and scalable electrochemical asymmetric protocol with metal-free catalysts and even without additional oxidants for the cross-dehydrogenative coupling reaction(CDC)of two C(sp^(3))-H bonds is reported.A series of aldehydes including natural products and various substrates containing C(sp^(3))-H bonds including xanthenes,acridines,cycloheptatrienes and even diarylmethane have been shown to undergo asymmetric CDC to afford a series of carbon-carbon bond coupling products with up to 94%yield and 98%ee.Mechanistic studies such as radical clock experiment suggest that the reaction proceeds via nucleophilic attack by enamine under electrochemical conditions.展开更多
基金supported by the National Natural Science Foundation of China(Nos.22201049,22471046)the Ba-Gui Youth Top-notch Talents Project of Guangxithe National HighLevel Personnel of Special Support Program for Young Top-notch Talents(9th batch)。
文摘The selective addition reaction of unsaturated C-C bonds has always been a classic and constant research topic.Different from well-developed hydroboration,hydrosilylation,and hydrostannylation reaction,hydrogermylation reaction remains challenging which hasn't been much reported.Herein,we developed a new metal-porous ligand polymers Pd1@POL-PPh_(n)Cy_(m)(n+m=3)with monoatomic dispersion characteristics for highly selective and efficient hydrogermylation of unsaturated C-C bonds,including alkynes,alkenes,and allenes.X-ray photoelectron spectroscopy and theoretical calculations further proved the introduction of cyclohexyl could gently adjust the charge on monoatomic Pd center which effectively facilitate the recognition and transformation of various substrates.With the electrically fine-tuned single atom palladium catalysts,we realized theα-germanium addition for the first time,obtaining corresponding allyl germanium and alkyl germanium compounds.
基金National Natural Science Foundation of China(Nos.22161008,22061003)Guangxi Science and Technology Base and Talent Project(High Level Innovative Talents and Team Training)(Guike No.AD23026094)Guangxi Natural Science Foundation of China(No.2021GXNSFFA220005)for financial support。
文摘An efficient and scalable electrochemical asymmetric protocol with metal-free catalysts and even without additional oxidants for the cross-dehydrogenative coupling reaction(CDC)of two C(sp^(3))-H bonds is reported.A series of aldehydes including natural products and various substrates containing C(sp^(3))-H bonds including xanthenes,acridines,cycloheptatrienes and even diarylmethane have been shown to undergo asymmetric CDC to afford a series of carbon-carbon bond coupling products with up to 94%yield and 98%ee.Mechanistic studies such as radical clock experiment suggest that the reaction proceeds via nucleophilic attack by enamine under electrochemical conditions.
