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=== Mechanism ===
A mechanism for the reaction has been suggested based on [[density functional theory]] calculations.<ref>{{cite journal |author1=F Himo |author2=T Lovell |author3=R Hilgraf |author4=VV Rostovtsev |author5=L Noodleman |author6=KB Sharpless |author7=VV Fokin | title = Copper(I)-Catalyzed Synthesis of Azoles, DFT Study Predicts Unprecedented Reactivity and Intermediates | year = 2005 | journal = [[Journal of the American Chemical Society]] | pages = 210–216 | doi = 10.1021/ja0471525 |pmid=15631470 | volume = 127|issue=1 }}</ref> Copper is a 1st row [[transition metal]]. It has the electronic configuration [Ar] 3d<sup>10</sup> 4s<sup>1</sup>. The copper (I) species generated in situ forms a [[pi complex]] with the triple bond of a terminal alkyne. In the presence of a base, the terminal hydrogen, being the most acidic, is deprotonated first to give a Cu [[acetylide]] intermediate. Studies have shown that the reaction is [[second order reaction|second order]] with respect to Cu. It has been suggested that the transition state involves two copper atoms.<ref>{{Cite journal|last=Rodionov|first=Valentin O.|last2=Fokin|first2=Valery V.|last3=Finn|first3=M. G.|date=2005-04-08|title=Mechanism of the Ligand-Free CuI-Catalyzed Azide–Alkyne Cycloaddition Reaction|journal=Angewandte Chemie International Edition|language=en|volume=44|issue=15|pages=2210–2215|doi=10.1002/anie.200461496|pmid=15693051|issn=1521-3773}}</ref><ref>{{Cite journal|last=Worrell|first=B. T.|last2=Malik|first2=J. A.|last3=Fokin|first3=V. V.|date=2013-04-26|title=Direct Evidence of a Dinuclear Copper Intermediate in Cu(I)-Catalyzed Azide-Alkyne Cycloadditions
The reaction is assisted by the copper, which, when coordinated with the acetylide lowers the pKa of the alkyne C-H by up to 9.8 units. Thus under certain conditions, the reaction may be carried out even in the absence of a base.
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The proposed mechanism suggests that in the first step, the [[spectator ligand]]s undergo displacement reaction to produce an [[activated complex]] which is converted, through [[oxidative coupling]] of an alkyne and an azide to the ruthenium containing metallocyle (Ruthenacycle). The new [[carbon-nitrogen bond|C-N bond]] is formed between the more electronegative and less sterically demanding carbon of the alkyne and the terminal nitrogen of the azide. The metallacycle intermediate then undergoes reductive elimination releasing the aromatic triazole product and regenerating the catalyst or the activated complex for further reaction cycles.
Cp<sup>*</sup>RuCl(PPh<sub>3</sub>)<sub>2</sub>, Cp<sup>*</sup>Ru(COD) and Cp<sup>*</sup>[RuCl<sub>4</sub>] are commonly used ruthenium catalysts. Catalysts containing cyclopentadienyl (Cp) group are also used. However, better results are observed with the pentamethylcyclopentadienyl(Cp<sup>*</sup>) version. This may be due to the sterically demanding Cp<sup>*</sup> group which facilitates the displacement of the spectator ligands.<ref>{{cite journal | authors = Li Zhang, Xinguo Chen, Peng Xue, Herman H. Y. Sun, Ian D. Williams, K. Barry Sharpless, Valery V. Fokin, and Guochen Jia
[[File:RuAAC mechanism.png|center|450px|Mechanism for ruthenium-catalysed click chemistry]]
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