Quantum Physics From Abstract to Laboratory Space I. Q-States Sustained by Partite Material Systems: Linking A+B and AxB domains via Entanglement

TL;DR

This paper explores how entangled quantum states, or q-states, serve as bridges linking non-interacting and interacting quantum systems, enabling transport phenomena and information exchange between matter and electromagnetic fields.

Contribution

It introduces the concept of bridge states as entangled states connecting different quantum domains, expanding understanding of quantum measurement and system interactions.

Findings

Entangled bridge states connect A+B and AxB quantum domains.

Transport of energy and angular momentum occurs via entangled states.

Matter and radiation states can exchange information through entanglement.

Abstract

The paper focuses on aspects of the measurement problem introducing quantum states (q-states) for measured and measuring systems. The link between non-interacting and interacting quantum systems is first look at. For two independent partite systems logical sums A+B stand for non-interacting q-systems; while a direct product space AxB gathers interacting states. However this latter should support physical q-states with base states that do not separately belong to either A nor B; the latter correspond to bridge states, namely entangled states that can perform as links (bridges) between A+B and AxB domains. Bridge states at laboratory space open possibilities to describe transport in quantized amounts of energy and angular momentum. These link bases sustain entanglements of different kinds. Interactions bring in quantized electromagnetic (em) fields. Matter sustained q-states entangled to em-sustained q-states open bridges to transport information between matter and radiation.