Photonic Framework to Handle Physical and Chemical Processes: Quantum Entanglement, Coherence, De-coherence, Re-coherence and the Roles of Multipartite Base States

TL;DR

This paper introduces a quantum photonic framework that models physical and chemical processes through entanglement, coherence, and re-coherence, emphasizing the construction and interpretation of photonic quantum states in experimental contexts.

Contribution

It presents a novel quantum framework utilizing a photonic basis-set to analyze physical and chemical phenomena, moving away from classical interpretations.

Findings

Quantum effects like entanglement and coherence are fundamental to chemical processes.

The framework enables analysis of quantum states in experimental settings.

Material states remain unchanged while quantum dynamics are driven by low-frequency EM radiation.

Abstract

A quantum framework, according quantum theories of electromagnetic (EM)radiation to matter response, leads to a handy scheme addressed to examine both physical and chemical processes. Fundamental quantum effects such asentanglement, coherence, de-coherence and re-coherence yield a fully quantum physical presentation applicable to chemical processes. A photonic basis-set obtains including all possibilities accessible to a system in abstract space; electronuclear (EN) base states put in resonance by photon fields are the ground where quantum states, q-states, would show time evolution. At laboratory space where energy and angular momentum conservation hold quantum dynamics (i.e. amplitude changes) is to be driven by low frequency EM radiation, e.g. microwaves. Materiality sustaining q-states unchanged.Here, focus on construction and reading of photonic quantum states that underlie a host of physical processes recently submitted to experimental examination. The approach moves away interpretational issues using classical physics language to focus on apprehending quantum states including experimental information.