35909-57-0Relevant articles and documents
Iron-Catalyzed Ligand Free α-Alkylation of Methylene Ketones and β-Alkylation of Secondary Alcohols Using Primary Alcohols
Alanthadka, Anitha,Bera, Sourajit,Banerjee, Debasis
, p. 11676 - 11686 (2019)
Herein, we demonstrate a general and broadly applicable catalytic cross coupling of methylene ketones and secondary alcohols with a series of primary alcohols to disubstituted branched ketones. A simple and nonprecious Fe2(CO)9 catalyst enables one-pot oxidations of both primary and secondary alcohols to a range of branched gem-bis(alkyl) ketones. A number of bond activations and formations selectively occurred in one pot to provide the ketone products. Coupling reactions can be performed in gram scale and successfully applied in the synthesis of an Alzehimer's drug. Alkylation of a steroid hormone can be achieved. A single catalyst enables sequential one-pot double alkylation to bis-hetero aryl ketones using two different alcohols. Preliminary mechanistic studies using an IR probe, deuterium labeling, and kinetic experiments established the participation of a borrowing-hydrogen process using Fe catalyst, and the reaction produces H2 and H2O as byproducts.
Transition-metal-free and base promoted C-C bond formationviaC-N bond cleavage of organoammonium salts
Chen, Tieqiao,Huang, Tianzeng,Ke, Yuting,Li, Chunya,Liu, Long,Tang, Yuanyuan,Tang, Zhi,Wang, Kunyu,Zhang, Tao
supporting information, p. 8237 - 8240 (2021/10/12)
A transition-metal-free and base promoted C-C bond forming reaction of benzyl C(sp3)-H bond with organoammonium saltsviaC-N bond cleavage has been reported. Benzyl ammonium salts as well as cinnamyl ammonium salt could couple readily with various benzyl C(sp3)-H species, producing the corresponding products in moderate to excellent yields with good functional group tolerance. Late stage chemical manipulation enabled the specific 1,2-diarylethane structure of products transformed into useful olefin compoundsviadehydrogenation, which further demonstrated the utility of this reaction.
Mn(ii)-catalysed alkylation of methylene ketones with alcohols: Direct access to functionalised branched products
Kabadwal, Lalit Mohan,Das, Jagadish,Banerjee, Debasis
supporting information, p. 14069 - 14072 (2019/01/03)
Herein an operationally simple alkylation of methylene ketones with primary alcohols is reported. Use of an inexpensive and earth abundant Mn/1,10-phenanthroline system enables direct access to a series of functionalised branched ketones including one-pot sequential double alkylation and Alzheimer's drug donepezil. Preliminary mechanistic investigation, determination of the rate and order of reactions and deuterium labeling experiments support the participation of the hydrogen-borrowing strategy for the ketone alkylation.
NNN pincer Ru(II)-complex-catalyzed α-alkylation of ketones with alcohols
Cao, Xiao-Niu,Wan, Xiao-Min,Yang, Fa-Liu,Li, Ke,Hao, Xin-Qi,Shao, Tian,Zhu, Xinju,Song, Mao-Ping
, p. 3657 - 3668 (2018/04/14)
A series of novel ruthenium(II) complexes supported by a symmetrical NNN ligand were prepared and fully characterized. These complexes exhibited good performance in transfer hydrogenation to form new C-C bonds using alcohols as the alkylating agents, generating water as the only byproduct. A broad range of substrates, including (hetero)aryl- or alkyl-ketones and alcohols, were well tolerated under the optimized conditions. Notably, α-substituted methylene ketones were also investigated, which afforded α-branched steric hindrance products. A potential application of α-alkylation of methylene acetone to synthesize donepezil was demonstrated, which provided the desired product in 83% yield. Finally, this catalytic system could be applied to a one-pot double alkylation procedure with sequential addition of two different alcohols. The current protocol is featured with several characteristics, including a broad substrate scope, low catalyst (0.50 mol %) loadings, and environmental benignity.
