High-fidelity quantum teleportation through noisy channels via weak measurement and environment-assisted measurement

TL;DR

This paper introduces a novel quantum teleportation protocol that maintains high fidelity through noisy amplitude damping channels by combining environment-assisted measurement and weak measurement techniques, applicable to various entangled states.

Contribution

The proposed protocol achieves perfect teleportation fidelity with a single entangled state and suppresses decoherence in controlled teleportation, outperforming existing methods.

Findings

Achieves unit fidelity with a single entangled state.

Suppresses decoherence in controlled teleportation with W states.

Outperforms previous teleportation protocols in simulations.

Abstract

A perfect teleportation protocol requires pure maximally shared entangled states. While in reality the shared entanglement is severely degraded due to the inevitable interaction with the noisy environment, which leads to mixed entangled state and extremely deteriorates the performance of teleportation. Here, we propose a teleportation protocol to teleport an unknown qubit through the amplitude damping channels with a fidelity up to one with a single copy of the entangled state. Our proposed teleportation protocol, while illustrated using the Bell and W entangled states as examples, can be utilized with any type of entangled states. In our protocol we employ environment-assisted measurement during the entanglement distribution, and further modify the original teleportation protocol by applying weak measurement in the last step of teleportation. We find a balance between teleportation fidelity and success probability by varying the strength of the weak measurement. Furthermore, we investigate the protection of controlled teleportation protocols, where all the qubits of the entangled state pass through the amplitude damping channel. In particular, for the controlled teleportation with the W state, the decoherence of the shared entanglement can be totally suppressed by using EAM, hence no weak measurement is required to achieve an average teleportation fidelity of unity. The numerical simulation results reveal that our proposed teleportation protocol outperforms both the weak measurement based probabilistic teleportation protocol and the original teleportation protocol without protection.