London Dispersion as a Design Element in Molecular Catalysis.

Key Points

London dispersion interactions are essential for understanding chemical selectivity in catalyzed reactions.
The study emphasizes the importance of LD as a design element alongside traditional concepts like steric hindrance.
Noncovalent interactions, including LD, contribute to the stabilization of reaction intermediates in catalysis.
Recognizing the role of LD can enhance strategies for catalyst development and improve reaction outcomes.

Abstract

This Perspective describes the role of London dispersion (LD) interactions as a key factor controlling chemical selectivity. LD arises from the correlated motion of electrons, leading to subtle yet significant stabilization ("steric attraction"), and counterbalances, together with other noncovalent interactions, Pauli exchange repulsion ("steric hindrance"). While chemists have largely relied on the latter to rationalize selectivities in catalyzed reactions, we emphasize here the role LD plays as a key design element in chemical reactions, in particular, for catalyst development.

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London Dispersion as a Design Element in Molecular Catalysis.

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Abstract

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