Multipartite entanglement generation with dipole induced transparency effect in indirectly coupled dipole-microcavity systems

Zhaohui Peng; Chunxia Jia; Yuqing Zhang; Zhonghua Zhu; Xiaojuan Liu

doi:10.3788/COL201816.082702

Journals >Chinese Optics Letters >Volume 16 >Issue 8 >Page 082702 > Article

Chinese Optics Letters
Vol. 16, Issue 8, 082702 (2018)

Multipartite entanglement generation with dipole induced transparency effect in indirectly coupled dipole-microcavity systems

Zhaohui Peng^1、*, Chunxia Jia^1、2, Yuqing Zhang¹, Zhonghua Zhu¹, and Xiaojuan Liu¹

Author Affiliations

¹Institute of Modern Physics and Department of Physics, Hunan University of Science and Technology, Xiangtan 411201, China

²Key Laboratory of Low-Dimensional Quantum Structures and Quantum Control of Ministry of Education, Department of Physics, Hunan Normal University, Changsha 410081, China

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DOI: 10.3788/COL201816.082702 Cite this Article Set citation alerts

Zhaohui Peng, Chunxia Jia, Yuqing Zhang, Zhonghua Zhu, Xiaojuan Liu. Multipartite entanglement generation with dipole induced transparency effect in indirectly coupled dipole-microcavity systems[J]. Chinese Optics Letters, 2018, 16(8): 082702 Copy Citation Text

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Schematic of generating multipartite entanglement of dipole emitters in three dipole-microcavity systems. (a) The energy-level configuration of the dipole emitter. The transition |gL(R)〉 ↔ |e〉 is driven by left (right) circularly polarized light. (b) Three indirectly coupled dipole-microcavity systems.

Fig. 1. Schematic of generating multipartite entanglement of dipole emitters in three dipole-microcavity systems. (a) The energy-level configuration of the dipole emitter. The transition |gL(R)〉 ↔ |e〉 is driven by left (right) circularly polarized light. (b) Three indirectly coupled dipole-microcavity systems.

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Power transmission |Tm|2 for three indirectly coupled dipole-microcavity systems with Purcell factor Fp=200 of each system. Tm denotes the transmission coefficient in the case where the incident photon is coupling with m dipole emitters, respectively. The dipole-microcavity parameters (g,κs,γa)=(0.33,10−3,10−3)κ1 are taken into account.

Fig. 2. Power transmission |Tm|2 for three indirectly coupled dipole-microcavity systems with Purcell factor Fp=200 of each system. Tm denotes the transmission coefficient in the case where the incident photon is coupling with m dipole emitters, respectively. The dipole-microcavity parameters (g,κs,γa)=(0.33,10−3,10−3)κ1 are taken into account.

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Fig. 3. Fidelities of the three-qubit GHZ state (black solid), W state (red dashed), and Dicke state (blue dot-dashed) against the Purcell factor of the dipole-microcavity system.

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