Mechanism of the Deprotonation Reaction of Alkyl Benzyl Ethers with <i>n</i>‐Butyllithium

Raposo, Maria Luz; Fernández‐Nieto, Fernando; García‐Río, Luis; Rodríguez‐Dafonte, Pedro; Paleo, M. Rita; Sardina, F. Javier

doi:10.1002/chem.201204467

Cited by 7 publications

(5 citation statements)

References 67 publications

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“…To reduce the irreversible reaction, a -V 2 O 5 was treated with n -BuLi, which is a strong base that reacts with acidic surface hydroxyl groups. , An expectation here is the decrease of H 2 evolution due to the removal of surface hydroxyl groups. Figure a shows the FT-IR spectra for two a -V 2 O 5 samples.…”

Section: Resultsmentioning

confidence: 99%

Reversible Lithium Storage at Highly Populated Vacant Sites in an Amorphous Vanadium Pentoxide Electrode

Chae¹,

Kim²,

Park³

et al. 2014

Chem. Mater.

152

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A vanadium pentoxide electrode is prepared in the amorphous form (a-V2O5), and its electrode performances are compared to those for its crystalline counterpart (c-V2O5). The a-V2O5 electrode outperforms c-V2O5 in several ways. First, it is free from irreversible phase transitions and Li trapping, which evolve in c-V2O5, probably due to the lack of interactions between the inserted Li+ ions/electrons and V2O5 matrix. Second, the absence of Li trapping allows a reversible capacity amounting to >600 mA h g–1, which is larger than that given by c-V2O5. Third, it shows an excellent rate property. The notably high reversible capacity and rate capability seem to be due to Li storage at vacant sites that are ill-defined but numerous in a-V2O5, which Li+ ions can easily access. However, irreversible capacity of a-V2O5 is appreciable in the first cycle due to a parasitic Li reaction with surface hydroxyl groups. Treatment with n-butyllithium can suppress the irreversible capacity by removing the surface hydroxyl groups.

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Section: Resultsmentioning

confidence: 99%

Reversible Lithium Storage at Highly Populated Vacant Sites in an Amorphous Vanadium Pentoxide Electrode

Chae¹,

Kim²,

Park³

et al. 2014

Chem. Mater.

152

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“…Because reactivity is strongly dependent on n- BuLi aggregation, the lithiation of benzyl ether 1 follows a pathway in which n -BuLi tetramer–dimer deaggregation occurs in a fast equilibrium step, followed by dimer complexation to the oxygen atom of the ether, and a subsequent proton transfer as the rate-determining step . When the same mechanistic scheme is applied to the lithiation of ester 2 , a rate equation is obtained, k obs = K 1 k 2 [dimer] ( K 1 and k 2 being the precomplexation equilibrium and proton transfer rate constants respectively), which predicts a linear dependence between the observed rate constant and [dimer] (see Figure , right).…”

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confidence: 95%

“…Our studies on the lithiation of benzyl methyl ether ( 1 ) (Figure ) with n -BuLi in THF/hexane at −80 °C showed that a precoordination step between base and acid occurs prior to the rate-determining proton transfer reaction. We now describe the results of a study on the lithiation of benzyl ester 2 and carbamate 3 , substrates analogous to ether 1 in which the O -substituents show enhanced donor ability.…”

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confidence: 99%

“…Because reactivity is strongly dependent on n-BuLi aggregation, 10 the lithiation of benzyl ether 1 follows a pathway in which n-BuLi tetramer−dimer deaggregation occurs in a fast equilibrium step, followed by dimer complexation to the oxygen atom of the ether, and a subsequent proton transfer as the rate-determining step. 9 When the same mechanistic scheme is applied to the lithiation of ester 2, a rate equation is obtained,…”

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The Two Alternative Rate-Determining Steps in Benzylic Lithiation Reactions of Esters and Carbamates

et al. 2016

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Lithiation reactions of tertiary benzylic esters and carbamates have been studied. Kinetic methodology revealed that a two-step reaction pathway should be considered for these reactions, where either the lithium precomplexation and/or the proton transfer steps can be rate determining. Kinetic isotopic effects were evaluated by comparison of the lithiations of the corresponding protio/deutero substrates, and the results obtained support the notion that lithium precomplexation is taking place on the reaction pathway and that it is the rate-determining step in this transformation.

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“…13 Similarly, Garcia-Rio et al have identified, by kinetics and NMR measurements, a dimer of n-BuLi solvated by 3 THF and on which the substrate of a deprotonation docks before the reaction starts. 14 The situation is also very clear for LDA, the disolvated dimer (LDA) 2 -2THF of which has been depicted in solution. 15 The electrophile we have retained is propanal, viz.…”

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confidence: 98%

Base or nucleophile? DFT finally elucidates the origin of the selectivity between the competitive reactions triggered by MeLi or LDA on propanal

et al. 2015

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Mechanism of the Deprotonation Reaction of Alkyl Benzyl Ethers with n‐Butyllithium

Cited by 7 publications

References 67 publications

Reversible Lithium Storage at Highly Populated Vacant Sites in an Amorphous Vanadium Pentoxide Electrode

Reversible Lithium Storage at Highly Populated Vacant Sites in an Amorphous Vanadium Pentoxide Electrode

The Two Alternative Rate-Determining Steps in Benzylic Lithiation Reactions of Esters and Carbamates

Base or nucleophile? DFT finally elucidates the origin of the selectivity between the competitive reactions triggered by MeLi or LDA on propanal

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