{"id":3470,"date":"2026-05-18T06:49:11","date_gmt":"2026-05-18T13:49:11","guid":{"rendered":"https:\/\/coherencegeometry.com\/?p=3470"},"modified":"2026-05-18T08:24:39","modified_gmt":"2026-05-18T15:24:39","slug":"atomic-orbitals-via-coherence-geometry","status":"publish","type":"post","link":"https:\/\/coherencegeometry.com\/index.php\/2026\/05\/18\/atomic-orbitals-via-coherence-geometry\/","title":{"rendered":"Atomic Orbitals via Coherence Geometry"},"content":{"rendered":"\n

Internal ID:<\/strong> CGI-RSR-000024
Author(s):<\/strong> Barry L. Petersen
Document Type:<\/strong> Research Paper
Publication Date:<\/strong> May 2026
Original Creation Date:<\/strong> September 7, 2025
Revised Document Date:<\/strong> N\/A
Status:<\/strong> Public
Domains:<\/strong> Chemistry, Physics
Sub-Domain:<\/strong> Quantum Chemistry
Research Topics:<\/strong> Atomic orbitals, orbital morphogenesis, nodal topology<\/p>\n\n\n\n

Abstract<\/h3>\n\n\n\n


This paper introduces a geometric framework for the spontaneous emergence of atomic orbital structures from curvature-driven field dynamics, independent of quantum mechanical postulates. Within Petersen\u2019s Coherence Geometry (CG) framework, orbitals arise as metastable attractors in a real-valued amplitude field, shaped by angular tension gradients and curvature bifurcations. Starting from isotropic initial conditions, the system evolves toward familiar nodal geometries such as \\(p_x\\), \\(p_z\\), \\(d_{z^2}\\), \\(f_{z^3}\\), and \\(g_{z^4}\\)\u2014all without imposing eigenfunction bases, boundary constraints, or complex-valued wavefunctions. The resulting orbital shapes are not approximations or heuristic visualizations, but precise topological equivalents of those derived from the Schr\u00f6dinger equation. Each configuration reproduces the correct number, orientation, and type of nodal surfaces expected for its orbital class. By encoding phase relationships and spatial distortion through geometric tension, the CG framework offers a physically grounded alternative to conventional orbital theory\u2014unifying orbital formation and structure under a single real-valued dynamical principle. These results suggest the existence of a deeper geometric substrate underlying orbital identity\u2014one in which nodal topology emerges not from imposed quantization, but from the spontaneous self-organization of curvature fields. This approach provides a new lens for understanding atomic structure and may lay the groundwork for extending geometric methods into bonding, spin, and unified field modeling.<\/p>\n\n\n\n

Representative Figure<\/h3>\n\n\n\n
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