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Mechanistic Insights for Iodane Mediated Aromatic Halogenation Reactions

Zheng‐Wang Qu, Hui Zhu, Stefan Grimme

2020ChemCatChem10 citationsDOIOpen Access PDF

Abstract

Abstract Stable iodanes such as PhI(OAc) 2 (Ac=acetyl) may be readily activated by electrophiles and salts for useful functional group transfer reactions under mild conditions, but the underlying reaction mechanism remains controversial. In this work, a general mechanism of iodane‐mediated aromatic halogenation is revealed by extensive DFT calculations using PhI(OAc) 2 and anisole PhOMe as model iodane and aromatic substrate, respectively. It is shown that facile OAc/X (X=Cl, Br) ligand exchange with electrophiles can be induced by electrophilic attack at acetyl C=O groups of PhI(OAc) 2 to form more reactive iodanes, especially the non‐symmetric iodanes PhI(X)OAc that can be activated by electrophiles to reach reactive iodonium PhIX + for further electrophilic halonium X + transfer to aromatic substrates. Direct anionic OAc − /X − exchange of iodane are 4∼7 kcal/mol endergonic, suggesting the crucial role of electrophilic iodane activation. Hetero‐ and homolytic I−X bond cleavages of neutral iodanes are more than 28 kcal/mol endergonic and thus unlikely under ambient conditions without electrophilic activation.

Topics & Concepts

ElectrophileChemistryAnisoleHalogenationMedicinal chemistryHomolysisLigand (biochemistry)NucleophileElectrophilic aromatic substitutionRadicalOrganic chemistryCatalysisReceptorBiochemistryVanadium and Halogenation ChemistryOxidative Organic Chemistry ReactionsCatalytic C–H Functionalization Methods
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