Toward a Quantum Definition of π in Molecular Systems: Original Formula, Mathematical Framework, and Foundational Implications
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Barack Ndenga
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Abstract
I propose an operational definition of a quantum π for molecular systems — a dimensionless, system-specific invariant π_q that generalizes the classical constant π to include electronic-phase topology and density-weighted phase winding of delocalized electrons. I define π_q via a density-weighted winding-number of the complex electronic amplitude around chemically relevant cycles (rings or effective closed paths), and I show how π_q reduces to the classical π in canonical limits (simple particle-on-a-ring, uniform density). I derive the formula from the Madelung (polar) decomposition of molecular wavefunctions, demonstrate its mathematical properties (gauge invariance, additivity under non-overlapping cycles, continuity under weak perturbations), and relate π_q to observable quantities: energy spacing of ring modes, current (ring magnetism), and phase-sensitive spectroscopic signals. I illustrate the concept analytically (particle-on-a-ring), semi-analytically (Hückel benzene), and numerically (finite conjugated chain model). Finally I discuss implications for aromaticity, molecular electronics, and a program to test π_q experimentally.
Quantum pi
Molecular topology
Electronic phase continuity
Electron delocalization
Aromaticity
Quantum chemistry
Wavefunction periodicity
Molecular orbital theory
Topological descriptors
Phase coherence
Electronic structure
Quantum-π series
Conjugated systems
Molecular resonance
Description
This work introduces Quantum π, a new molecular descriptor that extends the classical constant π into quantum chemistry. I define Quantum π as a measure of electronic phase continuity, delocalization strength, and topological coherence in molecular systems. The article presents a clear conceptual definition, a full theoretical foundation, and a step-by-step mathematical demonstration written in accessible scientific language.
Quantum π emerges naturally from the periodic behavior of electronic wavefunctions and provides a unified framework to characterize conjugation, aromaticity, and electronic resonance. I show that perfectly conjugated cyclic molecules display Quantum π equal to the classical π, while distorted or partially conjugated systems exhibit reduced values. This formalism opens a new perspective on molecular topology, electronic structure, and the quantification of phase-based properties.
This publication is part of the Quantum-π Series, a collection of research articles exploring the role of π in quantum mechanics, quantum chemistry, probability, and molecular structure.