Two-mode squeezing of distant nitrogen-vacancy-center ensembles by manipulating the reservoir

W. L. Yang; Z. Q. Yin; Q. Chen; C. Y. Chen; M. Feng

doi:10.1103/PhysRevA.85.022324

Two-mode squeezing of distant nitrogen-vacancy-center ensembles by manipulating the reservoir

W. L. Yang^*
, Z. Q. Yin
, Q. Chen
, C. Y. Chen
, M. Feng

^*Corresponding author for this work

CAS - Innovation Academy for Precision Measurement Science and Technology
University of Science and Technology of China
Tsinghua University
Hunan University of Humanities, Science and Technology

Research output: Contribution to journal › Article › peer-review

37 Citations (Scopus)

Abstract

We present a scheme to engineer a two-mode squeezed state of effective bosonic modes realized by collective excitations of two distant nitrogen-vacancy-center ensembles (NVEs) coupled to separated transmission line resonators (TLRs), which are interconnected by a current-biased Josephson-junction superconducting qubit. By making use of the engineered NVE-TLR magnetic coupling with Raman transition between the ground sublevels of the NVEs, we may manipulate the artificial reservoir by tuning the external driving fields. The TLR decay induces an artificial reservoir, which can drive the system to the desired entangled squeezed states. Our idea provides a scalable way to a NVE-based continuous-variable quantum-information processing, which is close to being achievable with currently available technology.

Original language	English
Article number	022324
Journal	Physical Review A - Atomic, Molecular, and Optical Physics
Volume	85
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevA.85.022324
Publication status	Published - 17 Feb 2012
Externally published	Yes

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title = "Two-mode squeezing of distant nitrogen-vacancy-center ensembles by manipulating the reservoir",

abstract = "We present a scheme to engineer a two-mode squeezed state of effective bosonic modes realized by collective excitations of two distant nitrogen-vacancy-center ensembles (NVEs) coupled to separated transmission line resonators (TLRs), which are interconnected by a current-biased Josephson-junction superconducting qubit. By making use of the engineered NVE-TLR magnetic coupling with Raman transition between the ground sublevels of the NVEs, we may manipulate the artificial reservoir by tuning the external driving fields. The TLR decay induces an artificial reservoir, which can drive the system to the desired entangled squeezed states. Our idea provides a scalable way to a NVE-based continuous-variable quantum-information processing, which is close to being achievable with currently available technology.",

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AU - Yang, W. L.

AU - Yin, Z. Q.

AU - Chen, Q.

AU - Chen, C. Y.

AU - Feng, M.

PY - 2012/2/17

Y1 - 2012/2/17

N2 - We present a scheme to engineer a two-mode squeezed state of effective bosonic modes realized by collective excitations of two distant nitrogen-vacancy-center ensembles (NVEs) coupled to separated transmission line resonators (TLRs), which are interconnected by a current-biased Josephson-junction superconducting qubit. By making use of the engineered NVE-TLR magnetic coupling with Raman transition between the ground sublevels of the NVEs, we may manipulate the artificial reservoir by tuning the external driving fields. The TLR decay induces an artificial reservoir, which can drive the system to the desired entangled squeezed states. Our idea provides a scalable way to a NVE-based continuous-variable quantum-information processing, which is close to being achievable with currently available technology.

AB - We present a scheme to engineer a two-mode squeezed state of effective bosonic modes realized by collective excitations of two distant nitrogen-vacancy-center ensembles (NVEs) coupled to separated transmission line resonators (TLRs), which are interconnected by a current-biased Josephson-junction superconducting qubit. By making use of the engineered NVE-TLR magnetic coupling with Raman transition between the ground sublevels of the NVEs, we may manipulate the artificial reservoir by tuning the external driving fields. The TLR decay induces an artificial reservoir, which can drive the system to the desired entangled squeezed states. Our idea provides a scalable way to a NVE-based continuous-variable quantum-information processing, which is close to being achievable with currently available technology.

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JO - Physical Review A - Atomic, Molecular, and Optical Physics

JF - Physical Review A - Atomic, Molecular, and Optical Physics

IS - 2

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ER -

Two-mode squeezing of distant nitrogen-vacancy-center ensembles by manipulating the reservoir

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