105578-59-4Relevant articles and documents
Internal Catalysis in Covalent Adaptable Networks: Phthalate Monoester Transesterification As a Versatile Dynamic Cross-Linking Chemistry
Delahaye, Maarten,Winne, Johan M.,Du Prez, Filip E.
, p. 15277 - 15287 (2019)
Covalent adaptable networks (CANs) often make use of highly active external catalysts to provide swift exchange of the dynamic chemical bonds. Alternatively, milder species can act as internal catalysts when covalently attached to the matrix and in close proximity to the dynamic bonds. In this context, we introduce the dynamic exchange of phthalate monoesters as a novel chemistry platform for covalent adaptable networks. A low-molecular-weight (MW) model study shows that these monoesters undergo fast transesterification via a dissociative mechanism, caused by internal catalysis of the free carboxylic acid, which reversibly forms an activated phthalic anhydride intermediate. Using this dynamic chemistry, a wide series of CANs with a broad range of properties have been prepared by simply curing a mixture of diols and triols with bifunctional phthalic anhydrides. The dynamic nature of the networks was confirmed via recycling experiments for multiple cycles and via stress relaxation using rheology. The networks proved to be resistant to deformation but showed a marked temperature response in their rheological behavior, related to the swift exchange reactions that have a high activation energy (120 kJ/mol). While densely cross-linked and hydrolytically stable polyester networks with low soluble fractions can be obtained, we found that, by swelling the networks in a hot solvent, a gel-to-sol transition happened, which resulted in the full dissolution of the network.
Nucleophilic acyl substitutions of anhydrides with protic nucleophiles catalyzed by amphoteric, oxomolybdenum species
Chen, Chien-Tien,Kuo, Jen-Huang,Pawar, Vijay D.,Munot, Yogesh S.,Weng, Shieu-Shien,Ku, Cheng-Hsiu,Liu, Cheng-Yuan
, p. 1188 - 1197 (2007/10/03)
(Chemical Equation Presented) Among six different group VIb oxometallic species examined, dioxomolybdenum dichloride and oxomolybdenum tetrachloride were the most efficient catalysts to facilitate nucleophilic acyl substitution (NAS) of anhydrides with a myriad array of alcohols, amines, and thiols in high yields and high chemoselectivity. In contrast to the well-recognized redox chemical behaviors associated with oxomolybdenum(VI) species, the catalytic NAS was unprecedented and tolerates virtually all kinds of functional groups. By using benzoic anhydride as a mediator for in situ generation of an incipient mixed anhydride-MoO2Cl2 adduct with a given functional alkanoic acid, one can achieve oleate, dipeptide, diphenylmethyl, N-Fmoc-α-amino, pyruvic, and tert-butylthio ester, N-tert-butylamide, and trityl methacrylate syntheses with appropriate protic nucleophiles. The amphoteric character of the Mo=O unit in oxomolybdenum chlorides was found to be responsible for the catalytic NAS profile as supported by a control NAS reaction of using an authentic adduct-MoOCl2(O2-CBu t)2 between pivalic anhydride and MoO2Cl 2 as the catalyst.
Catalytic nucleophilic acyl substitution of anhydrides by amphoteric vanadyl triflate
Chen, Chien-Tien,Chang, I-Hsin,Lin, Jin-Sheng,Liu, Chin-Jing,Chou, Y-Chen,Kuo, Jen-Huang,Li, Chun-Hsin,Barhate,Hon, Sang-Wen,Li, Tai-Wei,Chao, Shi-Deh,Liu, Chia-Cheng,Li, Ying-Chieh
, p. 3729 - 3732 (2007/10/03)
Figure presented Among four vanadyl species examined, vanadyl triflate was the most efficient catalyst to facilitate nucleophilic acyl substitution of anhydrides with a myriad array of alcohols, amines, and thiols in high yields and high chemoselectivity. By using mixed-anhydride technique, one can achieve oleate and peptide syntheses. In marked contrast to common metal Inflates, the amphoteric character of the V=O unit in vanadyl species was proven to be responsible for the catalytic profile in this process.