Paper Info
Title
DFT studies on the mechanism of Ag2CO3-catalyzed hydroazidation of unactivated terminal alkynes with TMS-N3: An insight into the silver(I) activation mode.
Abstract
Silver-mediated hydroazidation of unactivated alkynes has been developed as a new method for the synthesis of vinyl azides. Density functional theory calculations toward this reaction reveal that terminal alkynes with TMS-N3 participated hydroazidation proceed through HN3 formation, deprotonation and silver acetylides formation, nucleophilic addition, and protonation of terminal carbon by AgHCO3. It is also found that water molecules and activation modes of Ag (I) have a significant influence on the title reaction mechanism. Initially, catalyst Ag2CO3 coordinates preferentially with internal N atom of TMS–N3 to assist water as hydrogen source and proton-shuttle in facilitating HN3 formation. Then, the regioselective anti-addition of HN3 to triple bond of active silver-acetylide or ethynyl carbinols affords product vinyl azide via Ag–C σ-bond activation or Ag…C π-coordination activation modes, and the former one is more favorable. The origin of the difference regioselectivity is ascribed to the electronic and orbital effects of the reactive sites. Moreover, Ag2CO3 is the critical catalyst, acting as activator, base, and stabilizer to promote the HN3 and vinyl azide formation. Water molecule plays an important role as proton shuttle to promote HN3 and key active silver acetylides formation, thus improving the yield of product. © 2017 Wiley Periodicals, Inc.
Year
Venue
Field
2017
Journal of Computational Chemistry
Catalysis,Protonation,Chemistry,Nucleophilic addition,Triple bond,Regioselectivity,Azide,Photochemistry,Reaction mechanism,Deprotonation
DocType
Volume
Issue
Journal
38
27
Citations 
PageRank 
References 
0
0.34
0
Authors
4
Name
Order
Citations
PageRank
Haiyan Yuan101.69
Pin Xiao200.34
Yiying Zheng300.68
Jingping Zhang497.30