Graph approach to quantum teleportation dynamics

TL;DR

This paper introduces a graph theory-based symbolic framework to analyze quantum teleportation dynamics, explicitly illustrating entanglement and information flow, and demonstrates its application to various entangled states.

Contribution

It presents a novel graph-based approach with auxiliary elements for a dynamical, step-by-step understanding of quantum teleportation, linking it to traditional state vector methods.

Findings

Successfully models bipartite, tripartite, and tetrapartite teleportation cases

Establishes correspondence between graph approach and state vector formalism

Proposes a general protocol for multi-qubit entangled systems

Abstract

Quantum teleportation plays a key role in modern quantum technologies. Thus, it is of much interest to generate alternative approaches or representations aimed at allowing us a better understanding of the physics involved in the process from different perspectives. With this purpose, here an approach based on graph theory is introduced and discussed in the context of some applications. Its main goal is to provide a fully symbolic framework for quantum teleportation from a dynamical viewpoint, which makes explicit at each stage of the process how entanglement and information swap among the qubits involved in it. In order to construct this dynamical perspective, it has been necessary to define some auxiliary elements, namely virtual nodes and edges, as well as an additional notation for nodes describing potential states (against nodes accounting for actual states). With these elements, not only the flow of the process can be followed step by step, but they allow us to establish a direct correspondence between this graph-based approach and the usual state vector description. To show the suitability and versatility of this graph-based approach, several particular teleportation examples are examined, which include bipartite, tripartite and tetrapartite maximally entangled states as quantum channels. From the analysis of these cases, a general protocol is discussed in the case of sharing a maximally entangled multi-qubit system.