29179-25-7Relevant articles and documents
Fluorescent Molecular Logic Gates Driven by Temperature and by Protons in Solution and on Solid
West, Matthew E. S.,Yao, Chao-Yi,Melaugh, Gavin,Kawamoto, Kyoko,Uchiyama, Seiichi,de Silva, A. Prasanna
supporting information, p. 13268 - 13274 (2021/08/06)
Temperature-driven fluorescent NOT logic is demonstrated by exploiting predissociation in a 1,3,5-trisubstituted Δ2-pyrazoline on its own and when grafted onto silica microparticles. Related Δ2-pyrazolines become proton-driven YES an
Bu4NHSO4-Catalyzed Direct N-Allylation of Pyrazole and its Derivatives with Allylic Alcohols in Water: A Metal-Free, Recyclable and Sustainable System
Zhuang, Hongfeng,Lu, Nan,Ji, Na,Han, Feng,Miao, Chengxia
supporting information, p. 5461 - 5472 (2021/09/29)
Allylic amines are valuable and functional building blocks. Direct N-allylation of pyrazole and its derivatives as an atom economic strategy to provide allylic amines has been achieved only using commercial Bu4NHSO4 as the metal-free catalyst and water as the solvent without any additives. 11–93% isolated yields were obtained for the N-allylation of pyrazole and its derivatives with allylic alcohols. Bu4NHSO4 could be reused for six times by simple extraction nearly without loss of catalytic activity and was also suitable for a gram-scale production. The reaction of allylic ether and pyrazole did not occur to give the desired product indicated that allylic ether was not the active intermediate in the pathway. Density functional theory (DFT) calculations reveal that there are hydrogen bonding effects among substrates, solvent and catalyst, especially the one formed between allylic alcohol and H2O. Control experiments in different protic solvents further demonstrate the intermolecular hydrogen bonding of allylic alcohol and water. (Figure presented.).
Mechanochemical Syntheses of N-Containing Heterocycles with TosMIC
Bolm, Carsten,Molitor, Claude,Rissanen, Kari,Schumacher, Christian,Smid, Sabrina,Truong, Khai-Nghi
, p. 14213 - 14222 (2021/09/07)
A mechanochemical van Leusen pyrrole synthesis with a base leads to 3,4-disubstitued pyrroles in moderate to excellent yields. The developed protocol is compatible with a range of electron-withdrawing groups and can also be applied to the synthesis of oxazoles. Attempts to mechanochemically convert the resulting pyrroles into porphyrins proved to be difficult.