157636-81-2Relevant articles and documents
Ag(i)/PPh3-catalyzed diastereoselective syntheses of spiro[indole-3,4′-piperidine] derivatives via cycloisomerizations of tryptamine-ynamides
Chen, Yanyu,Cheng, Maosheng,Lin, Bin,Liu, Yongxiang,Sun, Shitao,Wang, Zhaobo,Yang, Lu,Zhang, Di,Zhang, Junpeng,Zhao, Wutong
supporting information, p. 3051 - 3054 (2022/03/16)
A Ag(i)/PPh3-catalyzed chelation-controlled cycloisomerization of tryptamine-ynamide was developed to access the spiro[indole-3,4′-piperidine] scaffold in a racemic and diastereoselective manner. The diastereoselective products were achieved by a chiron approach. Density functional theory (DFT) calculations indicated that strong non-covalent effects between the substrate and catalyst/ligand complex stabilized the spiroindoleninium intermediate via cation-π-π interactions.
Visible-Light-Mediated Liberation and In Situ Conversion of Fluorophosgene
Petzold, Daniel,Nitschke, Philipp,Brandl, Fabian,Scheidler, Veronica,Dick, Bernhard,Gschwind, Ruth M.,K?nig, Burkhard
supporting information, p. 361 - 366 (2018/11/23)
The first example for the photocatalytic generation of a highly electrophilic intermediate that is not based on radical reactivity is reported. The single-electron reduction of bench-stable and commercially available 4-(trifluoromethoxy)benzonitrile by an organic photosensitizer leads to its fragmentation into fluorophosgene and benzonitrile. The in situ generated fluorophosgene was used for the preparation of carbonates, carbamates, and urea derivatives in moderate to excellent yields via an intramolecular cyclization reaction. Transient spectroscopic investigations suggest the formation of a catalyst charge-transfer complex-dimer as the catalytic active species. Fluorophosgene as a highly reactive intermediate, was indirectly detected via its next downstream carbonyl fluoride intermediate by NMR. Furthermore, detailed NMR analyses provided a comprehensive reaction mechanism including a water dependent off-cycle equilibrium.
Catalytic fluoride triggers dehydrative oxazolidinone synthesis from CO2
Takada, Yuki,Foo, Siong Wan,Yamazaki, Yusuke,Saito, Susumu
, p. 50851 - 50857 (2015/02/19)
Herein, catalytic fluoride (F-) is demonstrated to be a trigger for dehydrative immobilization of atmospheric pressure CO2, such that reaction of CO2 with β-amino alcohols derived from natural amino acids gives optically pure oxazolidinones in high yields. A synergistic combination of fluoride and organosilicon agents (e.g., Bu4NF + Ph3SiF or siloxanes) enhances the catalytic activity and functional group compatibility. This system lies at the interface between homogenous and heterogeneous catalysis, and may prove useful for the development of recoverable/reusable siloxane-based CO2 immobilization materials. This journal is
