Quantum Matter-Photonics Framework: Analyses of Chemical Conversion Processes

TL;DR

This paper introduces a quantum Matter-Photonics framework to analyze chemical reaction mechanisms, emphasizing quantum states, entanglement, and coherence to better understand chemical conversions.

Contribution

It reformulates chemical bond concepts within a quantum framework, integrating entanglement and resonance states to enhance understanding of chemical reaction processes.

Findings

Quantum states and entanglement are pivotal in chemical conversion mechanisms.

The framework provides a full quantum physical perspective on chemical changes.

Analysis of chemical processes via energy eigenvalue spectra offers new insights.

Abstract

A quantum Matter-Photonics framework is adapted to help scrutinize chemical reaction mechanisms and used to explore a process mapped from chemical tree topological model. The chemical concept of bond knitting/breaking is reformulated via partitioned base sets leading to an abstract and general quantum presentation. Pivotal roles are assigned to entanglement, coherence,de-coherence and Feshbach resonance quantum states that permit apprehend gating states in conversion processes. A view from above in the state energy eigenvalue ladder, belonging to full system spectra complement the standard view from ground state. A full quantum physical view supporting chemical change obtains.