Experimental realization of a three-photon asymmetric maximally entangled state and its application to quantum teleportation

TL;DR

This paper experimentally creates a three-photon asymmetric high-dimensional entangled state and demonstrates its use in quantum teleportation, transferring information from two qubits to a four-dimensional ququart with high fidelity.

Contribution

It reports the first experimental realization of a three-photon asymmetric maximally entangled state and its application to high-dimensional quantum teleportation.

Findings

Achieved fidelities of 0.79 to 0.86 in teleportation

Confirmed nonclassical four-dimensional teleportation surpassing classical limits

Demonstrated potential for quantum information transfer between different dimensions

Abstract

Quantum entanglement is a fundamental resource for quantum information processing and is widely used in quantum communication, quantum computation and quantum metrology. Early research on quantum entanglement mainly focus on qubit states, but in recent years, more and more research has begun to focus on high-dimensional entangled states. Compared with qubit entangled states, higher-dimensional entangled states have a larger information capacity and the potential to realize more complex quantum applications. In this Letter, we have experimentally prepared a special high-dimensional entangled state, the so-called three-photon asymmetric maximally entangled state, which consists of two two-dimensional photons and one four-dimensional photon. Using this asymmetric maximally entangled state as a resource, we have also implemented a proof-of-principle quantum teleportation experiment, realizing the transfer of quantum information from two qubits to a single ququart. The fidelities of the quantum teleportation range from 0.79 to 0.86, which are well above both the optimal single-copy ququart state-estimation limit of 2/5 and maximal qutrit-ququart overlap of 3/4, thus confirming a genuine and nonclassical four-dimensional teleportation. The asymmetric entangled state realized here has the potential to be used as a quantum interface in future quantum networks, allowing quantum information transfer between quantum objects of different dimensions via the quantum teleportation protocol demonstrated in this work.