41215-40-1Relevant articles and documents
Multicomponent Ugi Reaction of Indole- N-carboxylic Acids: Expeditious Access to Indole Carboxamide Amino Amides
Zeng, Linwei,Sajiki, Hironao,Cui, Sunliang
supporting information, p. 5269 - 5272 (2019/07/03)
A novel multicomponent Ugi-type reaction for the synthesis of indole carboxamide amino amides from aldehydes, amines, isocyanides, and indole-N-carboxylic acids, which were simply prepared from indoles and CO2, is described. This method provides an expeditious and practical access to indole tethered peptide units, along with the achievement of remarkable structural diversity and brevity. Gram-scale reaction was conducted to demonstrate the scalability, and the products could be transformed to new indole derivatives.
N-doped carbon supported Pd catalysts for N-formylation of amines with CO2/H2
Luo, Xiaoying,Zhang, Hongye,Ke, Zhengang,Wu, Cailing,Guo, Shien,Wu, Yunyan,Yu, Bo,Liu, Zhimin
, p. 725 - 731 (2018/04/02)
Using mesoporous N-doped carbons (NCs) derived from glucose and melamine as the supports, a series of Pd/NC catalysts were prepared, in which Pd nanoparticles with average size2 and H2 in ethanol without any additives. Especially, the catalyst Pd/NC-800-6.9% containing quaternary N showed the best performance, affording a series of formylamides in good or even excellent yields. Further investigation reveals that the interaction between the Pd nanoparticles and quaternary nitrogen in the NC support was responsible for the good performance of the catalyst.
Production of Formamides from CO and Amines Induced by Porphyrin Rhodium(II) Metalloradical
Zhang, Jiajing,Zhang, Wentao,Xu, Minghui,Zhang, Yang,Fu, Xuefeng,Fang, Huayi
supporting information, p. 6656 - 6660 (2018/05/24)
It is of fundamental importance to transform carbon monoxide (CO) to petrochemical feedstocks and fine chemicals. Many strategies built on the activation of C≡O bond by π-back bonding from the transition metal center were developed during the past decades. Herein, a new CO activation method, in which the CO was converted to the active acyl-like metalloradical, [(por)Rh(CO)]? (por = porphyrin), was reported. The reactivity of [(por)Rh(CO)]? and other rhodium porphyrin compounds, such as (por)RhCHO and (por)RhC(O)NHnPr, and corresponding mechanism studies were conducted experimentally and computationally and inspired the design of a new conversion system featuring 100% atom economy that promotes carbonylation of amines to formamides using porphyrin rhodium(II) metalloradical. Following this radical based pathway, the carbonylations of a series of primary and secondary aliphatic amines were examined, and turnover numbers up to 224 were obtained.