Atomic entanglement purification and concentration using coherent state input-output process in low-Q cavity QED regime

We propose two efficient entanglement concentration protocols (ECPs) for arbitrary less-entangled single-photon entanglement state, in which the photon qubit has the polarization feature. The first ECP is in linear optics, and the second ECP is in nonlinear optics. The two ECPs have some attractive advantages. First, they can preserve the polarization feature of the photon qubit, while all the other existing ECPs for single photon state cannot achieve this goal. Second, they only require one pair of less-entangled single-photon entanglement state and some auxiliary single photons. Third, they only require local operations. Especially, the second ECP can be used repeatedly, which can increase its success probability largely. Based on above properties, our two ECPs, especially the second one may be useful in current and future quantum communication.

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“…In this way, Bob can finally make the HOM interference measurement [75,76]. After the BS1, | 3 a1b2b5b6 will evolve to:…”

Section: The First Ecp For the Single-photon Spatial Entanglementmentioning

confidence: 99%

Efficient Concentration Protocols for the Single-Photon Entanglement State with Polarization Feature

Zhou

Wang

et al. 2017

Front. Phys.

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“…[45,46] Based on the GCB, deterministic photon-spin quantum interfaces (entangling gates) could be built, and several schemes for scalable QIP with single QD spins and single photons have been proposed. [47][48][49][50][51][52][53][54][55][56][57][58][59][60][61][62][63] In particular, universal quantum controlled gates on photons, [64][65][66][67][68] electron spins, [69][70][71][72][73] and photon-spin hybrid systems [74,75] could be implemented. In 2011, Young et al [76] experimentally investigated the QD-induced phase shift in a pillar microcavity.…”

Section: Introductionmentioning

confidence: 99%

High‐Fidelity Universal Quantum Controlled Gates on Electron‐Spin Qubits in Quantum Dots Inside Single‐Sided Optical Microcavities

et al. 2019

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Semiconductor quantum‐dot (QD) spins hold great promise in quantum information science and technology. The implementation of high‐fidelity quantum gates on QD‐spin qubits is of great importance. Here, two schemes are presented to implement two universal quantum controlled gates, that is, the two‐qubit controlled‐not gate and the three‐qubit Toffoli gate, on stationary electron‐spin qubits in QDs inside single‐sided optical microcavities, based on the cavity‐assisted photon scattering under the balance condition. Compared with the previous schemes based on the ideal giant circular birefringence, the present schemes use the balance condition of the single‐sided QD‐cavity system, which can be achieved in both the weak‐ and strong‐coupling regimes of cavity quantum electrodynamics. Under the balance condition, the noise caused by the unbalanced reflectance between the coupled and uncoupled QD‐cavity systems can be efficiently depressed, so that the fidelity of each quantum gate operation can be increased to unity in principle. The schemes exhibit the possibility of realizing high‐fidelity and scalable quantum computing with single QD spins and single photons using the feasible and robust light–matter quantum interface. These high‐fidelity quantum controlled gates can lead to more efficient construction of quantum circuits for quantum computing, and provide a convenient avenue for quantum networking.

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“…The precondition of the protocols is that the coefficients of the initial state should be accurately known to the remote parties beforehand. Moreover, entanglement concentration has also been widely studied in atomic systems 14,15,16,17,18 , which exhibit potential applications in quantum repeaters and networks. Recently, Wang et al 19 investigated the entanglement concentration process of valley qubits by exploiting the optical excitation selection rules in graphene quantum dots, which provides a fast, all-optical manipulation of on-chip qubits and gives an effective way for quantum information processing (QIP) in graphene-based solid systems.…”

Section: Introductionmentioning

confidence: 99%

Nonlocal hyperconcentration on entangled photons using photonic module system

Cao

Wang

et al. 2016

Annals of Physics

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Atomic entanglement purification and concentration using coherent state input-output process in low-Q cavity QED regime

Cited by 82 publications

References 67 publications

Efficient Concentration Protocols for the Single-Photon Entanglement State with Polarization Feature

Efficient Concentration Protocols for the Single-Photon Entanglement State with Polarization Feature

High‐Fidelity Universal Quantum Controlled Gates on Electron‐Spin Qubits in Quantum Dots Inside Single‐Sided Optical Microcavities

Nonlocal hyperconcentration on entangled photons using photonic module system

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