1095320-62-9Relevant academic research and scientific papers
Merging NiH Catalysis and Inner-Sphere Metal-Nitrenoid Transfer for Hydroamidation of Alkynes
Lyu, Xiang,Zhang, Jianbo,Kim, Dongwook,Seo, Sangwon,Chang, Sukbok
, p. 5867 - 5877 (2021)
The formal hydroamination/hydroamidation utilizing metal hydride is an appealing synthetic tool for the construction of valuable nitrogen-containing compounds from unsaturated hydrocarbons. While significant advances have been made for the functionalizations of alkenes in this realm, the direct hydroamidation of alkynes remains rather limited due to the high feasibility of the key metal-alkenyl intermediate to choose other reaction pathways. Herein, we report a NiH-catalyzed strategy for the hydroamidation of alkynes with dioxazolones, which allows convenient access to synthetically useful secondary enamides in (E)-anti-Markovnikov or Markovnikov selectivity. The reaction is viable for both terminal and internal alkynes and is also tolerant with a range of subtle functional groups. With H2O found as an essential component for high catalyst turnovers, the involvement of inner-sphere nitrenoid transfer is proposed that outcompetes an undesired semireduction process, thus representing the first example to show the competence of Ni catalysis for metal-nitrenoid formation from dioxazolones.
Ruthenium-catalyzed addition of primary amides to alkynes: A stereoselective synthesis of secondary enamides
Goossen, Lukas J.,Blanchot, Mathieu,Salih, Kifah S. M.,Goossen, Kaethe
experimental part, p. 2283 - 2288 (2009/12/27)
The anti-Markovnikov addition of primary amides to terminal alkynes under the formation of Z-configured secondary enamides is efficiently promoted by a catalyst system generated in situ from bis(2-methallyl)(cycloocta-1,5-diene) ruthenium(II), 1,4-bis(dic
Synthesis of secondary enamides by ruthenium-catalyzed selective addition of amides to terminal alkynes
Goossen, Lukas J.,Salih, Kifah S. M.,Blanchot, Mathieu
supporting information; experimental part, p. 8492 - 8495 (2009/05/11)
(Chemical Equation Presented) Enamides made easy: A catalyst system generated in situ using bis(2-methallyl)-(cycloocta-1,5-diene)ruthenium(II), 1,4-bis(dicyclohexylphosphino)butane, and ytterbium triflate efficiently catalyzes the addition of primary amides to terminal alkynes, selectively forming the Z-anti-Markovnikov enamides. The E isomers are also accessible by combining the hydroamidation with an in situ double-bond isomerization reaction.
