Publication: π and Delocalized Electrons: A Quantum-Chemical Reassessment of Coherence, Stability, and Molecular Structure
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Barack Ndenga
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Abstract
This article revisits the pivotal role of the mathematical constant π within the quantum-chemical framework describing delocalized electronic systems. Moving beyond its classical geometric interpretation, π is identified as a fundamental structural invariant intrinsic to the quantization, symmetry properties, and stability criteria of extended conjugated and aromatic molecules. By critically examining canonical theoretical constructs—including Hückel molecular orbital theory, analytical solutions to the particle-in-a-ring model, electron density distributions, and quantum spectral transitions—this work elucidates how π underpins key quantum mechanical boundary conditions, normalization protocols, and phase coherence phenomena essential for electronic delocalization. The analysis reveals that π governs the delicate balance between electronic wavefunction symmetry and energetic stabilization, thereby shaping aromaticity patterns and conjugation effects at a foundational quantum level. This comprehensive perspective advances a unifying conceptual framework positioning π as a universal quantum signature, thereby opening avenues for novel interpretations and extensions in molecular electronic structure theory and aromaticity research
Description
This article inaugurates the Quantum π in Chemistry series by exploring the fundamental role of the mathematical constant π in the behavior, symmetry, and quantum properties of delocalized electrons in molecular systems. I examine how π emerges naturally in wave-function periodicity, orbital topology, aromatic stabilization, and electron density distribution.
Building on quantum mechanics, molecular orbital theory, and topological chemistry, this work provides a unified perspective that interprets π not only as a mathematical ratio but as a structural parameter governing electronic coherence and delocalization.
The article reviews classical foundations and recent developments, including quantum-chemical computations, aromaticity indices, Berry phase connections, and π-electron quantization.
This study lays the groundwork for a deeper theoretical framework in which π functions as a quantum-structural invariant across molecular and supramolecular systems, opening the way for predictive models, advanced simulations, and new interpretations in chemical physics.