Litcius/Paper detail

Heralded high-fidelity quantum hyper-CNOT gates assisted by charged quantum dots inside single-sided optical microcavities

Yu‐Hong Han, Cong Cao, Ling Fan, Ru Zhang

2021Optics Express41 citationsDOIOpen Access PDF

Abstract

Photonic hyper-parallel quantum information processing (QIP) can simplify the quantum circuit and improve the information-processing speed, as well as reduce the quantum resource consumption and suppress the photonic dissipation noise. Here, utilizing the singly charged semiconductor quantum dot (QD) inside single-sided optical microcavity as the potentially experimental platform, we propose five schemes for heralded four-qubit hyper-controlled-not (hyper-CNOT) gates, covering all cases of four-qubit hyper-CNOT gates operated on both the polarization and spatial-mode degrees of freedom (DoFs) of a two-photon system. The novel heralding mechanism improves the fidelity of each hyper-CNOT gate to unity in principle without the strict restriction of strong coupling. The adaptability and scalability of the schemes make the hyper-CNOT gates more accessible under current experimental technologies. These heralded high-fidelity photonic hyper-CNOT gates can therefore have immense utilization potentials in high-capacity quantum communication and fast quantum computing, which are of far-reaching significance for QIP.

Topics & Concepts

Controlled NOT gatePhysicsQuantum gateQubitQuantum computerPhotonicsQuantum dotQuantum circuitQuantum networkQuantum error correctionQuantum channelQuantum informationTopology (electrical circuits)OptoelectronicsComputer scienceQuantum mechanicsQuantumElectrical engineeringEngineeringQuantum Information and CryptographySemiconductor Quantum Structures and DevicesNeural Networks and Reservoir Computing