Quantum teleportation and information splitting via four-qubit cluster state and a Bell state

AbstractEfficient all-photonic quantum teleportation requires fast and deterministic sources of highly indistinguishable and entangled photons. Solid-state-based quantum emitters—notably semiconductor quantum dots—are a promising candidate for the role. However, despite the remarkable progress in nanofabrication, proof-of-concept demonstrations of quantum teleportation have highlighted that imperfections of the emitter still place a major roadblock in the way of applications. Here, rather than focusing on source optimization strategies, we deal with imperfections and study different teleportation protocols with the goal of identifying the one with maximal teleportation fidelity. Using a quantum dot with sub-par values of entanglement and photon indistinguishability, we show that the average teleportation fidelity can be raised from below the classical limit to 0.842(14), adopting a polarization-selective Bell state measurement and moderate spectral filtering. Our results, which are backed by a theoretical model that quantitatively explains the experimental findings, loosen the very stringent requirements set on the ideal entangled-photon source and highlight that imperfect quantum dots can still have a say in teleportation-based quantum communication architectures.

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Experimental realization of a two-photon four-qubit cluster state from a single Bell-state photon pair

2007 Conference on Lasers and Electro-Optics - Pacific Rim ◽

10.1109/cleopr.2007.4391690 ◽

2007 ◽

Author(s):

Hee Su Park ◽

Jaeyoon Cho ◽

Jong Moon Park ◽

Jae Yong Lee ◽

Dong Hoon Lee ◽

...

Keyword(s):

Cluster State ◽

Bell State ◽

Photon Pair ◽

Experimental Realization ◽

Two Photon

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Practical quantum teleportation of an unknown quantum state

Canadian Journal of Physics ◽

10.1139/cjp-2016-0758 ◽

2017 ◽

Vol 95 (5) ◽

pp. 498-503

Author(s):

Syed Tahir Amin ◽

Aeysha Khalique

Keyword(s):

Quantum State ◽

Quantum Teleportation ◽

Bell State ◽

Linear Optics ◽

State Measurement ◽

Dark Counts ◽

Experimental Parameters ◽

Unknown Quantum State ◽

Down Conversion ◽

Good Agreement

We present our model to teleport an unknown quantum state using entanglement between two distant parties. Our model takes into account experimental limitations due to contribution of multi-photon pair production of parametric down conversion source, inefficiency, dark counts of detectors, and channel losses. We use a linear optics setup for quantum teleportation of an unknown quantum state by the sender performing a Bell state measurement. Our theory successfully provides a model for experimentalists to optimize the fidelity by adjusting the experimental parameters. We apply our model to a recent experiment on quantum teleportation and the results obtained by our model are in good agreement with the experimental results.

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Bidirectional Quantum Teleportation of Two-Qubit State Via Four-Qubit Cluster State

International Journal of Theoretical Physics ◽

10.1007/s10773-018-3919-8 ◽

2018 ◽

Vol 58 (1) ◽

pp. 150-156 ◽

Cited By ~ 10

Author(s):

Ri-Gui Zhou ◽

Chen Qian ◽

Hou Ian

Keyword(s):

Quantum Teleportation ◽

Cluster State ◽

Qubit State ◽

Bidirectional Quantum Teleportation

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Superdense Coding and Quantum Teleportation

An Introduction to Quantum Computing ◽

10.1093/oso/9780198570004.003.0008 ◽

2006 ◽

Author(s):

Phillip Kaye ◽

Raymond Laflamme ◽

Michele Mosca

Keyword(s):

Quantum Teleportation ◽

Communication Channel ◽

Quantum Communication ◽

Communication Protocols ◽

Bell State ◽

Third Party ◽

Classical Communication ◽

Superdense Coding ◽

Communication Task ◽

Epr Pair

We are now ready to look at our first protocols for quantum information. In this section, we examine two communication protocols which can be implemented using the tools we have developed in the preceding sections. These protocols are known as superdense coding and quantum teleportation. Both are inherently quantum: there are no classical protocols which behave in the same way. Both involve two parties who wish to perform some communication task between them. In descriptions of such communication protocols (especially in cryptography), it is very common to name the two parties ‘Alice’ and ‘Bob’, for convenience. We will follow this tradition. We will repeatedly refer to communication channels. A quantum communication channel refers to a communication line (e.g. a fiberoptic cable), which can carry qubits between two remote locations. A classical communication channel is one which can carry classical bits (but not qubits).1 The protocols (like many in quantum communication) require that Alice and Bob initially share an entangled pair of qubits in the Bell state The above Bell state is sometimes referred to as an EPR pair. Such a state would have to be created ahead of time, when the qubits are in a lab together and can be made to interact in a way which will give rise to the entanglement between them. After the state is created, Alice and Bob each take one of the two qubits away with them. Alternatively, a third party could create the EPR pair and give one particle to Alice and the other to Bob. If they are careful not to let them interact with the environment, or any other quantum system, Alice and Bob’s joint state will remain entangled. This entanglement becomes a resource which Alice and Bob can use to achieve protocols such as the following. Suppose Alice wishes to send Bob two classical bits of information. Superdense coding is a way of achieving this task over a quantum channel, requiring only that Alice send one qubit to Bob. Alice and Bob must initially share the Bell state Suppose Alice is in possession of the first qubit and Bob the second qubit.

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