Multi-particle entanglement and generalized N-particle teleportation using quantum statistical correlations

TL;DR

This paper introduces a criterion based on quantum statistical correlations to construct and analyze multi-particle entangled states, enabling generalized N-particle teleportation with potential applications in quantum information processing.

Contribution

It presents a new method using quantum statistical correlations to determine maximum entanglement and generalize N-particle states for direct teleportation.

Findings

States remain entangled after partial traces

States can be generalized for any number of particles

Useful for N-particle direct teleportation

Abstract

Construction of multi-particle entangled states and direct teleportation of N-(spin 1/2) particles are important areas of quantum information processing. A number of different schemes which have been presented already, address the problem through controlled teleportation. In this article, a criterion based on standard quantum statistical correlations employed in the many body virial expansions is used to determine maximum entanglement for a N-particle state. These states remain entangled through proper traces to states for a smaller number of particles and can be generalized for arbitrary number of particles. It is shown that they are quite useful in generalized, N-particle, direct teleportation. The corresponding quantum gates are also indicated for teleportation schemes from simple computational basis states.