Your search keyword '"Shengshuai Liu"' showing total 5 results

1. All-Optical Entanglement Swapping.

Author

Shengshuai Liu, Yanbo Lou, Yingxuan Chen, and Jietai Jing

Subjects

*FOUR-wave mixing, *QUANTUM mechanics, *BELL'S theorem, *QUANTUM entanglement

Abstract

Entanglement swapping, which is a core component of quantum network and an important platform for testing the foundation of quantum mechanics, can enable the entangling of two independent particles without direct interaction both in discrete variable and continuous variable systems. Conventionally, the realization of entanglement swapping relies on the Bell-state measurement. In particular, for entanglement swapping in continuous variable regime, such Bell-state measurement involves the optic-electro and electro-optic conversion, which limits the applications of the entanglement swapping for constructing broadband quantum network. In this Letter, we propose and demonstrate a measurement-free all-optical entanglement swapping. In our scheme, a high-gain parametric amplifier based on the four-wave mixing process is exploited to realize the function of Bell-state measurement without detection, which avoids the introduction of the optic-electro and electro-optic conversion. Our results provide an all-optical paradigm for implementing entanglement swapping and pave the way to construct a measurement-free all-optical broadband quantum network. [ABSTRACT FROM AUTHOR]

Published

2022

2. Orbital Angular Momentum Multiplexed Quantum Dense Coding.

Author

Yingxuan Chen, Shengshuai Liu, Yanbo Lou, and Jietai Jing

Subjects

*ANGULAR momentum (Mechanics), *QUANTUM communication, *FOUR-wave mixing, *MULTIPLEXING, *CHANNEL capacity (Telecommunications), *SOURCE code

Abstract

To beat the channel capacity limit of conventional quantum dense coding (QDC) with fixed quantum resources, we experimentally implement the orbital angular momentum (OAM) multiplexed QDC (MQDC) in a continuous variable system based on a four-wave mixing process. First, we experimentally demonstrate that the Einstein-Podolsky-Rosen entanglement source coded on OAM modes can be used in a single channel to realize the QDC scheme. Then, we implement the OAM MQDC scheme by using the Einstein-Podolsky-Rosen entanglement source coded on OAM superposition modes. In the end, we make an explicit comparison of channel capacities for four different schemes and find that the channel capacity of the OAM MQDC scheme is substantially enhanced compared to the conventional QDC scheme without multiplexing. The channel capacity of our OAM MQDC scheme can be further improved by increasing the squeezing parameter and the number of multiplexed OAM modes in the channel. Our results open an avenue to construct high-capacity quantum communication networks. [ABSTRACT FROM AUTHOR]

Published

2021

3. Experimental Demonstration of a Multifunctional All-Optical Quantum State Transfer Machine.

Author

Yanbo Lou, Shengshuai Liu, and Jietai Jing

Subjects

*QUANTUM states, *MACHINE tools, *BEAM splitters, *QUANTUM teleportation, *COHERENT states, *ASPHALT pavers

Abstract

Quantum information protocol with quantum resources shows a great advantage in substantially improving security, fidelity, and capacity of information processing. Various quantum information protocols with diverse functionalities have been proposed and implemented. However, in general, the present quantum information system can only carry out a single information protocol or deal with a single communication task, which limits its practical application in the future. Therefore, it is essential to develop a multifunctional platform compatible with multiple different quantum information protocols. In this Letter, by utilizing an all-optical platform consisting of a gain-tunable parametric amplifier, a beam splitter, and an entanglement source, we experimentally realize the partially disembodied quantum state transfer protocol, which links the all-optical quantum teleportation protocol and the optimal 1→N coherent state cloning protocol. As a result, these three protocols, which have different physical essences and functionalities, are implemented in a single all-optical machine. In particular, we demonstrate that the partially disembodied quantum state transfer protocol can enhance the state transfer fidelity compared with all-optical quantum teleportation under the same strength of entanglement. Our all-optical quantum state transfer machine paves a way to implement the multifunctional quantum information system. [ABSTRACT FROM AUTHOR]

Published

2021

4. All-Optical Optimal N-to-M Quantum Cloning of Coherent States.

Author

Shengshuai Liu, Yanbo Lou, Yingxuan Chen, and Jietai Jing

Subjects

*BEAM splitters, *COHERENT states, *QUANTUM communication, *QUANTUM states, *FOUR-wave mixing, *QUANTUM mechanics

Abstract

The laws of quantum mechanics forbid the perfect copying of an unknown quantum state, known as the no-cloning theorem. In spite of this, approximate cloning with imperfect fidelity is possible, which opens up the field of quantum cloning. In general, quantum cloning can be divided into discrete variable and continuous variable (CV) categories. In the CV regime, all-optical implementation of the optimal N→M quantum cloning has been proposed in two original parallel works, which involves a parametric amplifier and a set of beam splitters and thus avoids the optic-electro and electro-optic conversions in the current CV quantum cloning technologies. However, such original proposal of all-optical CV optimal N→M quantum cloning scheme has never been experimentally implemented. Here, we show that optimal N→M quantum cloning of coherent states can be realized by utilizing a parametric amplifier based on four-wave mixing process in a hot atomic vapor and a set of beam splitters. In particular, we realize 1→M, 2→M, and 4→M quantum cloning. We find that the fidelity of N→M quantum cloning increases with the decrease of clone number M and the increase of original replica number N. The best cloning fidelity achieved in our experiment is about 93.3% ±1.0% in the 4→5 case. Our results may find potential applications in realizing all-optical high-fidelity quantum state transfer and all-optical high-compatibility eavesdropping attack in quantum communication networks. [ABSTRACT FROM AUTHOR]

Published

2021

5. Interference-Induced Quantum Squeezing Enhancement in a Two-beam Phase-Sensitive Amplifier.

Author

Shengshuai Liu, Yanbo Lou, and Jietai Jing

Subjects

*QUANTUM information science, *FOUR-wave mixing, *SQUEEZED light, *QUANTUM interference

Abstract

We experimentally demonstrate a method for realizing quantum squeezing enhancement which is induced by the interference in a two-beam phase-sensitive amplifier (PSA) based on a four-wave mixing process. Compared to the normal phase-insensitive amplifier with an intensity-difference squeezing (IDS) of 8.97±0.24 dB or 8.76±0.26 dB, the IDS of our two-beam PSA is enhanced to 10.13±0.21 dB under the same experimental situation. Furthermore, we study how various parameters influence the quantum squeezing enhancement of the PSA. These results clearly show that the physical mechanism inducing the IDS enhancement of the two-beam PSA is its intrinsic interference nature. Our results may find potential applications in improving the fidelity of quantum information processing and the precision of quantum metrology. [ABSTRACT FROM AUTHOR]

Published

2019