Lewis acid catalysis is a chemical process that is mainly based on the ability of protons and/or cationic metal atoms to attract electron density from atoms of external molecules and activate them towards the attack of a third chemical entity. However, the use of non-metal species, beyond protons, is much more scarce, in particular of heteroatoms in the low-valence state. Elemental phosphorus has apparently not been reported yet as a catalytic Lewis acid, since phosphorus (0) materials present the most of the atom unaccessible to outer reagents and with neutral or even anionic oxidation states. Here, the high degree of exfoliation in our 2D black phosphorus and antimonene, and the protection against oxidation given by the ionic liquid, allows for the co-adsorption and coupling of alkyl carbonyl compounds (esters) and benzene functionalities (i.e. benzyl alcohols), after formation and stabilization of alkyl carbocations on the lone electron pair network of P and Sb. This mechanism enables Lewis acid catalyzed processes in much milder conditions than with protons or metal cations, giving access to the alkylation of soft nucleophiles incompatible with the standard acid catalyzed conditions.
Few layer 2D pnictogens catalyze the alkylation of soft nucleophiles with esters
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Few layer 2D pnictogens catalyze the alkylation of soft nucleophiles with esters - Nature Communications
Group 15 elements in zero oxidation state, also called pnictogens, are rarely used in catalysis due to the difficulties in preparation. Here, the authors report on the synthesis of highly exfoliated, few layer 2D phosphorene and antimonene in zero oxidation state, and their use as efficient catalyst…
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