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Your search keyword '"Ren, Ya-long"' showing total 21 results
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21 results on '"Ren, Ya-long"'

1. Chiral cavity-magnonic system for the unidirectional emission of a tunable squeezed microwave field

Author

Xie, Ji-kun, Ma, Sheng-li, Ren, Ya-long, Gao, Shao-yan, and Li, Fu-li

Subjects
Quantum Physics
Abstract

Unidirectional photon emission is crucial for constructing quantum networks and realizing scalable quantum information processing. In the present work an efficient scheme is developed for the unidirectional emission of a tunable squeezed microwave field. Our scheme is based on a chiral cavity magnonic system, where a magnon mode in a single-crystalline yttrium iron garnet (YIG) sphere is selectively coupled to one of the two degenerate rotating microwave modes in a torus-shaped cavity with the same chirality. With the YIG sphere driven by a two-color Floquet field to induce sidebands in the magnon-photon coupling, we show that the unidirectional emission of a tunable squeezed microwave field can be generated via the assistance of the dissipative magnon mode and a waveguide. Moreover, the direction of the proposed one-way emitter can be controlled on demand by reversing the biased magnetic field. Our work opens up an avenue to create and manipulate one-way nonclassical microwave radiation field and could find potential quantum technological applications., Comment: to appear in Phys. Rev. A

Published
2023

2. Enhancing strength and range of atom-atom interaction in a coupled-cavity array via parametric drives

Author

Ren, Ya-long, Ma, Sheng-li, Zippilli, Stefano, Vitali, David, and Li, Fu-li

Subjects
Quantum Physics
Abstract

Coherent long-range interactions between atoms are a prerequisite for numerous applications in the field of quantum information science, but they usually decrease exponentially with the increase in atomic separation. Here we present an appealing method to dramatically enhance the long-range atom-atom interaction mediated by a coupled-cavity array that is subjected to two-photon (parametric) drives. Our method allows one to greatly amplify both the localization length of the single-photon bound-state wavefunction and the effective atom-photon coupling strength, resulting in a significant improvement of photon-mediated coherent interaction between two distant atoms. Additionally, we illustrate this effect by analyzing how it facilitates the transfer of information and the creation of entanglement between the atoms.

Published
2023
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3. Chiral coupling between a ferromagnetic magnon and a superconducting qubit

Author

Ren, Ya-long, Ma, Sheng-li, and Li, Fu-li

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

Chiral coupling at the single-quantum level promises to be a remarkable potential for quantum information processing. Here we propose to achieve a chiral interaction between a magnon mode in a ferromagnetic sphere and a superconducting qubit mediated by a one-dimensional coupled-cavity array. When the qubit is coupled to two lattice sites of the array and each one is encoded with a tunable phase, we can acquire a directional qubit-magnon interaction via the quantum interference effect. This work opens up a new route to construct chiral devices, which are expected to become a building block in quantum magnonic networks.

Published
2022
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4. Photon-pair blockade in a Josephson-photonics circuit with two nondegenerate microwave resonators

Author

Ma, Sheng-li, Xie, Ji-kun, Ren, Ya-long, Li, Xin-ke, and Li, Fu-li

Subjects
Quantum Physics
Abstract

We propose to generate photon-pair blockade in a Josephson-photonics circuit that consists of a dc voltage-biased Josephson junction in series with a superconducting charge qubit and two nondegenerate microwave resonators. The two-level charge qubit is utilized to create anticorrelations of the charge transport; that is, the simultaneous Cooper pair tunneling events are inhibited. When the Josephson frequency matches the sum of resonance frequencies of the charge qubit and the two resonators, we demonstrate that the two resonators can release their energies in the form of antibunched pairs of two strongly correlated photons. The present work provides a practical way for producing a bright microwave source of antibunched photon pairs, with potential applications ranging from spectroscopy and metrology to quantum information processing., Comment: Accepted for publication in New J. Phys

Published
2022
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21. Coupling a single NV center to a superconducting flux qubit via a nanomechanical resonator

Author

Li, Xin-Ke, Ma, Sheng-Li, Ren, Ya-Long, Xie, Ji-Kun, and Li, Fu-Li

Abstract

We investigate the hybrid quantum system of a superconducting flux qubit, a single electronic spin associated with a negatively charged nitrogen vacancy (NV) center in diamond, and a high-quality magnetized nanomechanical resonator (NAMR). It is shown that the quantized motion of the NAMR can strongly couple to both the NV spin and the flux qubit. We estimate that the coupling strength of the NAMR to both the NV spin and the flux qubit can be about 2π×100 kHz, which is one order of magnitude larger than direct spin–qubit coupling. This enables the quantum state transfer to be faster and more robust against decoherence. The present work may provide an appealing way for quantum information processing based on hybrid solid-state quantum systems.

Published
2022

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