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Chemical Bonding and the Role of Node-Induced Electron Confinement

Alistair J. Sterling, Daniel S. Levine, Abdulrahman Aldossary, Martin Head‐Gordon

2024Journal of the American Chemical Society15 citationsDOIOpen Access PDF

Abstract

The chemical bond is the cornerstone of chemistry, providing a conceptual framework to understand and predict the behavior of molecules in complex systems. However, the fundamental origin of chemical bonding remains controversial and has been responsible for fierce debate over the past century. Here, we present a unified theory of bonding, using a separation of electron delocalization effects from orbital relaxation to identify three mechanisms [node-induced confinement (typically associated with Pauli repulsion, though more general), orbital contraction, and polarization] that each modulate kinetic energy during bond formation. Through analysis of a series of archetypal bonds, we show that an exquisite balance of energy-lowering delocalizing and localizing effects are dictated simply by atomic electron configurations, nodal structure, and electronegativities. The utility of this unified bonding theory is demonstrated by its application to explain observed trends in bond strengths throughout the periodic table, including main group and transition metal elements.

Topics & Concepts

ChemistryChemical bondChemical physicsPi bondElectronegativityPauli exclusion principleDelocalized electronThree-center two-electron bondSingle bondElectronMolecular orbital theoryMoleculeAtomic orbitalComputational chemistryBond orderNanotechnologyValence bond theoryMolecular orbitalBond lengthQuantum mechanicsGroup (periodic table)PhysicsOrganic chemistryMaterials scienceAdvanced Chemical Physics StudiesCrystallography and molecular interactionsMolecular Junctions and Nanostructures
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