Activation of Diboron Reagents with Brønsted Bases and Alcohols: An Experimental and Theoretical Perspective of the Organocatalytic Boron Conjugate Addition Reaction

Bases play an important role in organocatalytic boron conjugate addition reactions. The sole use of MeOH and a base can efficiently transform acyclic and cyclic activated olefins into the corresponding β‐borated products in the presence of diboron reagents. Inorganic and organic bases deprotonate Me...

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Published in:Chemistry : a European journal 2012-01, Vol.18 (4), p.1121-1126
Main Authors: Pubill-Ulldemolins , Cristina, Bonet, Amadeu, Bo, Carles, Gulyás, Henrik, Fernández, Elena
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Language:English
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Boron
Chemistry
DFT
organocatalysis
reaction mechanisms
Reagents
synthetic methods
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Bonet, Amadeu
Bo, Carles
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Fernández, Elena
description Bases play an important role in organocatalytic boron conjugate addition reactions. The sole use of MeOH and a base can efficiently transform acyclic and cyclic activated olefins into the corresponding β‐borated products in the presence of diboron reagents. Inorganic and organic bases deprotonate MeOH in the presence of diboron reagents. It is concluded, on the basis of theoretical calculations, NMR spectroscopic data, and ESI‐MS experiments, that the methoxide anion forms a Lewis acid–base adduct with the diboron reagent. The sp2 B atom of the methoxide–diboron adduct gains a strongly nucleophilic character, and attacks the electron‐deficient olefin. The methanol protonates the intermediate, generating the product and another methoxide anion. This appears to be the simplest method to activate diboron reagents and make them suitable for incorporation into target organic molecules. The simplest method to activate diboron reagents and make them suitable for incorporation in targeted organic molecules seems to be deprotonation of MeOH by base (e.g., Verkade's base) to generate the methoxide anion, which interacts with the diboron reagent to give a nucleophilic Lewis acid–base adduct that promotes the β‐boration of α,β‐unsaturated carbonyl substrates. Methanol protonates the intermediate to generate the product and another methoxide anion (see scheme).
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subjects Boron
Chemistry
DFT
organocatalysis
reaction mechanisms
Reagents
synthetic methods
title Activation of Diboron Reagents with Brønsted Bases and Alcohols: An Experimental and Theoretical Perspective of the Organocatalytic Boron Conjugate Addition Reaction
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