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99 results on '"Wu, Huaizhi"'

1. Single-photon scattering in giant-atom waveguide systems with chiral coupling

Author

Li, Shu-Yu, Zhang, Ze-Quan, Du, Lei, Li, Yong, and Wu, Huaizhi

Subjects
Quantum Physics
Abstract

We study single-photon scattering spectra of a giant atom chirally coupled to a one-dimensional waveguide at multiple connection points, and examine chirality induced effects in the scattering spectra. We show that the transmission spectra typically possess an anti-Lorentzian lineshape with a nonzero minimum, but by engineering the chirality of the multi-point coupling, the transmission spectrum of an incident photon can undergo a transition from complete transmission to total reflection at multiple frequency ``windows'', where the width of the anti-Lorentzian lineshape for each of the window can be flexibly tuned at a fixed frequency detuning. Moreover, we show that a perfect nonreciprocal photon scattering can be achieved due to the interplay between internal atomic spontaneous emission and the chirally external decay to the waveguide, in contrast to that induced by the non-Markovian retardation effect. We also consider the non-Markovian retardation effect on the scattering spectra, which allows for a photonic band gap even with only two chiral coupling points. The giant-atom-waveguide system with chiral coupling is a promising candidate for realizing single-photon routers with multiple channels., Comment: 15 pages, 8 figures

Published
2024

2. Mechanical cooling in the bistable regime of a dissipative optomechanical cavity with a Kerr medium

Author

Liu, Ye, Liu, Yang, Hu, Chang-Sheng, Jiang, Yun-Kun, Wu, Huaizhi, and Li, Yong

Subjects
Quantum Physics
Abstract

In this paper, we study static bistability and mechanical cooling of a dissipative optomechanical cavity filled with a Kerr medium. The system exhibits optical bistability for a wide input-power range with the power threshold being greatly reduced, in contrast to the case of purely dissipative coupling. At the bistable regime, the membrane can be effectively cooled down to a few millikelvin from the room temperature under the unresolved sideband condition, where the effective mechanical temperature is a nonmonotonic function of intracavity intensity and reaches its minimum near the turning point of the upper stable branch. When the system is in the cryogenics environment, the effective mechanical temperature at the bistable regime shows a similar feature as in the room temperature case, but the optimal cooling appears at the monostable regime and approaches the mechanical ground state. Our results are of interest for further understanding bistable optomechanical systems, which have many applications in nonclassical state preparations and quantum information processing., Comment: 11 pages, 5 figures

Published
2023
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3. Enhanced sensing of optomechanically induced nonlinearity by linewidth suppression and optical bistability in cavity-waveguide systems

Author

Liu, Chun-Wang, Liu, Ye, Du, Lei, Su, Wan-Jun, Wu, Huaizhi, and Li, Yong

Subjects
Quantum Physics
Abstract

We study enhanced sensing of optomechanically induced nonlinearity (OMIN) in a cavity-waveguide coupled system. The Hamiltonian of the system is anti-PT symmetric with the two involved cavities being dissipatively coupled via the waveguide. When a weak waveguide-mediated coherent coupling is introduced, the anti-PT symmetry may break down. However, we find a strong bistable response of the cavity intensity to the OMIN near the cavity resonance, benefiting from linewidth suppression caused by the vacuum induced coherence. The joint effect of optical bistability and the linewidth suppression is inaccessible by the anti-PT symmetric system involving only dissipative coupling. Due to that, the sensitivity is greatly enhanced by two orders of magnitude compared to that for the anti-PT symmetric model. Moreover, the sensitivity shows resistances to a reasonably large cavity decay and robustness to fluctuations in the cavity-waveguide detuning. Based on the integrated optomechanical cavity-waveguide systems, the scheme can be used for sensing different physical quantities related to the single-photon coupling strength, and has potential applications in high-precision measurements with physical systems involving Kerr-type nonlinearity., Comment: 9 pages, 5 figures

Published
2022
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4. Fast spin squeezing by distance-selective long-range interactions with Rydberg molecule dressing

Author

Wu, Huaizhi, Lin, Xin-Yu, Ding, Zong-Xing, Zheng, Shi-Biao, Lesanovsky, Igor, and Li, Weibin

Subjects
Quantum Physics
Abstract

We propose a Rydberg molecule dressing scheme to create strong and long-ranged interactions at selective distances. This is achieved through laser coupling ground-state atoms off-resonantly to an attractive molecular curve of two interacting Rydberg atoms. Although dephasing due to Rydberg state decay occurs in all dressing schemes, an advantage of the molecule dressing is that a large ratio of dressed interaction to dephasing rate can be realized at large atomic separations. In an optical lattice or tweezer setting, we show that the strong interaction permits the fast generation of spin squeezing for several tens of dressed atoms. The proposed setting offers a new route to study complex many-body dynamics and to realize quantum information processing with non-convex long-range interactions., Comment: 5 pages, 4 figures. Supplementary Material of 6 pages, 2 figures

Published
2021
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5. Nonreciprocal light transmission via optomechanical parametric interactions

Author

Lan, Yan-Ting, Su, Wan-Jun, Wu, Huaizhi, Li, Yong, and Zheng, Shi-Biao

Subjects
Quantum Physics
Abstract

Nonreciprocal transmission of optical or microwave signals is indispensable in various applications involving sensitive measurements. In this paper, we study optomechanically induced directional amplification and isolation in a generic setup including two cavities and two mechanical oscillators by exclusively using blue-sideband drive tones. The input and output ports defined by the two cavity modes are coupled through coherent and dissipative paths mediated by the two mechanical resonators, respectively. By choosing appropriate transfer phases and strengths of the driving fields, either a directional amplifier or an isolator can be implemented at low thermal temperature, and both of them show bi-directional nonreciprocity working at two mirrored frequencies. The nonreciprocal device can potentially be demonstrated by opto- and electro-mechanical setups in both optical and microwave domains., Comment: 5 pages, 3 figures

Published
2021
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6. Manifestation of classical nonlinear dynamics in optomechanical entanglement with a parametric amplifier

Author

Hu, Chang-Sheng, Shen, Li-Tuo, Yang, Zhen-Biao, Wu, Huaizhi, Li, Yong, and Zheng, Shi-Biao

Subjects
Quantum Physics
Abstract

Cavity optomechanical system involving an optical parametric amplifier (OPA) can exhibit rich classical and quantum dynamical behaviors. By simply modulating the frequency of the laser pumping the OPA, we find two interesting parameter regimes, with one of them enabling to study quantum-classical correspondence in system dynamics, while there exist no classical counterparts of the quantum features for the other. For the former regime, as the parametric gain of OPA increases to a critical value, the classical dynamics of the optical or mechanical modes can experience a transition from the regular periodic oscillation to period-doubling motion, in which cases the light-mechanical entanglement can be well studied by the logarithm negativity and can manifest the dynamical transition in the classical nonlinear dynamics. Moreover, the optomechanical entanglement shows a second-order transition characteristic at the critical parametric gain. For the latter regime, the kind of normal mode splitting comes up in the laser detuning dependence of optomechanical entanglement, which is induced by the squeezing of the optical and mechanical hybrid modes and finds no classical correspondence. The OPA assisted optomechanical systems therefore offer a simple way to study and exploit quantum manifestations of classical nonlinear dynamics., Comment: 10 pages, 12 figures

Published
2019
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8. Dissipative entanglement preparation via Rydberg antiblockade and Lyapunov control

Author

Ding, Zong-Xing, Hu, Chang-Sheng, Shen, Li-Tuo, Yang, Zhen-Biao, Wu, Huaizhi, and Zheng, Shi-Biao

Subjects
Quantum Physics
Abstract

Preparation of entangled steady states via dissipation and pumping in Rydberg atoms has been recently found to be useful for quantum information processing. The driven-dissipative dynamics is closely related to the natural linewidth of the Rydberg states and can be usually modulated by engineering the thermal reservior. Instead of modifying the effectively radiative decay, we propose an alternatively optimized scheme, which combines the resonant Rydberg antiblockade excitation and the Lyapunov control of the ground states to speed up the prepration of the singlet state for two interacting Rydberg atoms. The acceleration process strongly depends on the initial state of the system with respect to the initial coherence between the singlet state and decoherence-sensitive bright state. We study the optimal parameter regime for fast entanglement preparation and the robustness of the fidelity against random noises. The numerical results show that a fidelity above 0.99 can be achieved around 0.4 ms with the current experimental parameters. The scheme may be generalized for preparation of more complicate multi-atom entangled states., Comment: 8 pages, 6 figures

Published
2018
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9. Robust Rydberg gate via Landau-Zener control of F\'orster resonance

Author

Huang, Xi-Rong, Ding, Zong-Xing, Hu, Chang-Sheng, Shen, Li-Tuo, Li, Weibin, Wu, Huaizhi, and Zheng, Shi-Biao

Subjects
Quantum Physics
Abstract

In this paper, we propose a scheme to implement the two-qubit controlled-Z gate via the Stark-tuned F\"orster interaction of Rydberg atoms, where the F\"orster defect is driven by a time-dependent electric field of a simple sinusoidal function while the matrix elements of the dipole-dipole interaction are time-independent. It is shown that when the system is initially in a specific state, it makes a cyclic evolution after a preset interaction time, returning to the initial state, but picks up a phase, which can be used for realizing a two-atom controlled-Z gate. Due to the interference of sequential Landau-Zener transitions, the population and phase of the state is quasi-deterministic after the cyclic evolution and therefore the gate fidelity is insensitive to fluctuations of the interaction time and the dipole-dipole matrix elements. Feasibility of the scheme realized with Cs atoms is discussed in detail, which shows that the two-qubit gate via Landau-Zener control can be realized with the state-of-the-art experimental setup., Comment: 8 pages, 8 figures

Published
2018
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10. Rydberg-interaction gates via adiabatic passage and phase control of driving fields

Author

Wu, Huaizhi, Huang, Xi-Rong, Hu, Chang-Sheng, Yang, Zhen-Biao, and Zheng, Shi-Biao

Subjects
Quantum Physics
Abstract

In this paperwe propose two theoretical schemes for implementation of quantum phase gates by engineering the phase-sensitive dark state of two atoms subjected to Rydberg-Rydberg interaction. Combining the conventional adiabatic techniques and currently developed approaches of phase control, a feasible proposal for implementation of a geometric phase gate is presented, where the conditional phase shift (Berry phase) is achieved by adiabatically and cyclically changing the parameters of the driving fields. Here we find that the geometric phase acquired is related to the way how the relative phase is modulated. In the second scheme, the system Hamiltonian is adiabatically changed in a noncyclic manner, so that the acquired conditional phase is not a Berry phase. A detailed analysis of the experimental feasibility and the effect of decoherence is also given. The proposed schemes provide new perspectives for adiabatic manipulation of interacting Rydberg systems with tailored phase modulation., Comment: 9 pages, 9 figures

Published
2018
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11. Twofold mechanical squeezing in a cavity optomechanical system

Author

Hu, Chang-Sheng, Yang, Zhen-Biao, Wu, Huaizhi, Li, Yong, and Zheng, Shi-Biao

Subjects
Quantum Physics
Abstract

We investigate the dynamics of an optomechanical system where a cavity with a movable mirror involves a degenerate optical parametric amplifier and is driven by a periodically modulated laser field. Our results show that the cooperation between the parametric driving and periodically modulated cavity driving results in a two-fold squeezing on the movable cavity mirror that acts as a mechanical oscillator. This allows the fluctuation of the mechanical oscillator in one quadrature (momentum or position) to be reduced to a level that cannot be reached by solely applying either of these two drivings. In addition to the fundamental interests, e.g., study of quantum effects at the macroscopic level and exploration of the quantum-to-classical transition, our results have potential applications in ultrasensitive sensing of force and motion., Comment: 8 pages, 3 figures

Published
2018
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12. Quantum signature for laser-driven correlated excitation of Rydberg atoms

Author

Wu, Huaizhi, Li, Yong, Yang, Zhen-Biao, and Zheng, Shi-Biao

Subjects
Quantum Physics
Abstract

The excitation dynamics of a laser-driven Rydberg gas exhibits a cooperative effect due to the interatomic Rydberg-Rydberg interaction, but the large many-body system with inhomogeneous Rydberg coupling is hard to exactly solved or numerically study by density matrix equations. In this paper, we find that the laser-driven Rydberg gas with most of the atoms being in the ground state can be described by a simplified interaction model resembling the optical Kerr effect if the distance-dependent Rydberg-Rydberg interaction is replaced by an infinite-range coupling. We can then quantitatively study the effect of the quantum fluctuations on the Rydberg excitation with the interatomic correlation involved and analytically calculate the statistical characteristics of the excitation dynamics in the steady state, revealing the quantum signature of the driven-dissipative Rydberg gas. The results obtained here will be of great interest for other spin-1/2 systems with spin-spin coupling., Comment: Main text (8 pages, 8 figures)

Published
2015
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15. Electromagnetically induced transparency with controlled van der Waals interaction

Author

Wu, Huaizhi, Bian, Meng-Meng, Shen, Li-Tuo, Chen, Rong-Xin, Yang, Zhen-Biao, and Zheng, Shi-Biao

Subjects
Quantum Physics, Physics - Atomic Physics
Abstract

We study the electromagnetically induced transparency (EIT) effect with two individually addressed four-level Rydberg atoms subjected to the interatomic van der Waals interaction. We derive an effectively atomic Raman transition model where two ladders of the usual Rydberg-EIT setting terminating at the same upper Rydberg level of long radiative lifetime are turned into a Rydberg-EIT lambda setup via two-photon transitions, leaving the middle levels of each ladder largely detuned from the coupling and probe laser beams. It can hence overcome the limits of applications for EIT with atoms of the ladder-type level configuration involving a strongly decaying intermediate state by inducing coherence between two ground states. By probing one of the atoms, we observe four doublets of absorption induced by the Autler-Townes (AT) splitting and the van der Waals interaction. In particular, we find that the location of the EIT center remains unchanged compared to the interatomic-interaction-free case, which demonstrated that the interference among the multiple transition channels is basically destructive. The EIT with controlled Rydberg-Rydberg interaction among few atoms provides a versatile tool for engineering the propagation dynamics of light., Comment: 5 pages, 4 figures

Published
2014
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16. Two-photon absorption and emission by Rydberg atoms in coupled cavities

Author

Wu, Huaizhi, Yang, Zhen-Biao, and Zheng, Shi-Biao

Subjects
Quantum Physics
Abstract

We study the dynamics of a system composed of two coupled cavities, each containing a single Rydberg atom. The interplay between Rydberg-Rydberg interaction and photon hopping enables the transition of the atoms from the collective ground state to the double Rydberg excitation state by individually interacting with the hybrid cavity modes and suppressing the up conversion process between them. The atomic transition is accompanied by the two-photon absorption and emission of the hybrid modes. Since the energy level structure of the atom-cavity system is photon number dependent, there is only a pair of states being in the two-photon resonance. Therefore, the system can act as a quantum nonlinear absorption filter through the nonclassical quantum process, converting coherent light field into a non-classical state. Meanwhile, the vacuum field in the cavity inspires the Rydberg atoms to simultaneously emit two photons into the hybrid mode, resulting in obvious emission enhancement of the mode., Comment: 7 pages, 6 figures

Published
2013
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17. Quantum teleportation and computation with Rydberg atoms in an optical lattice

Author

Wu, Huaizhi, Yang, Zhen-Biao, Shen, Li-Tuo, and Zheng, Shi-Biao

Subjects
Quantum Physics
Abstract

Neutral atoms excited to Rydberg states can interact with each other via dipole-dipole interaction, which results in a physical phenomenon named Rydberg blockade mechanism. The effect attracts much attention due to its potential applications in quantum computation and quantum simulation. Quantum teleportation has been the core protocol in quantum information science playing a key role in efficient long-distance quantum communication. Here, we first propose the implementation of teleportation scheme with neutral atoms via Rydberg blockade, in which the entangled states of qubits can readily be prepared and the Bell states measurements just require single qubit operations without precise control of Rydberg interaction. The rapid experimental progress of coherent control of Rydberg excitation, optical trapping techniques and state-selective atomic detection promise the application of the teleportation scheme for scalable quantum computation and many-body quantum simulation using the protocol proposed by D. Gottesman and I. L. Chuang [Nature (London) 402, 390 (1999)] with Rydberg atoms in optical lattice., Comment: 15 pages, 7 figures

Published
2013
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18. The effect of Landau-Zener dynamics on phonon lasing

Author

Wu, Huaizhi, Heinrich, Georg, and Marquardt, Florian

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Optomechanical systems couple light to the motion of nanomechanical objects. Intriguing new effects are observed in recent experiments that involve the dynamics of more than one optical mode. There, mechanical motion can stimulate strongly driven multi-mode photon dynamics that acts back on the mechanics via radiation forces. We show that even for two optical modes Landau-Zener-Stueckelberg oscillations of the light field drastically change the nonlinear attractor diagram of the resulting phonon lasing oscillations. Our findings illustrate the generic effects of Landau-Zener physics on back-action induced self-oscillations., Comment: 6 pages, 4 figures

Published
2011
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23. Mechanical cooling at the bistable regime of a dissipative optomechanical cavity with a Kerr medium

Author

Liu, Ye, Liu, Yang, Hu, Chang-Sheng, Jiang, Yun-Kun, Wu, Huaizhi, and Li, Yong

Subjects
FOS: Physical sciences, Quantum Physics (quant-ph)
Abstract

In this paper, we study static bistability and mechanical cooling of a dissipative optomechanical cavity filled with a Kerr medium. The system exhibits optical bistability for a wide input-power range with the power threshold being greatly reduced, in contrast to the case of purely dissipative coupling. At the bistable regime, the membrane can be effectively cooled down to a few millikelvin from the room temperature under the unresolved sideband condition, where the effective mechanical temperature is a nonmonotonic function of intracavity intensity and reaches its minimum near the turning point of the upper stable branch. When the system is in the cryogenics environment, the effective mechanical temperature at the bistable regime shows a similar feature as in the room temperature case, but the optimal cooling appears at the monostable regime and approaches the mechanical ground state. Our results are of interest for further understanding bistable optomechanical systems, which have many applications in nonclassical state preparations and quantum information processing., 10 pages, 5 figures

Published
2023
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27. Exceptional entanglement phenomena: non-Hermiticity meeting non-classicality

Author

Han, Peirong, Wu, Fan, Huang, Xinjie, Wu, Huaizhi, Zou, Chang-Ling, Yi, Wei, Zhang, Mengzhen, Li, Hekang, Xu, Kai, Zheng, Dongning, Fan, Heng, Wen, Jianming, Yang, Zhenbiao, and Zheng, Shibiao

Subjects
Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)
Abstract

Non-Hermitian (NH) extension of quantum-mechanical Hamiltonians represents one of the most significant advancements in physics. During the past two decades, numerous captivating NH phenomena have been revealed and demonstrated, but all of which can appear in both quantum and classical systems. This leads to the fundamental question: What NH signature presents a radical departure from classical physics? The solution of this problem is indispensable for exploring genuine NH quantum mechanics, but remains untouched upon so far. Here we resolve this basic issue by unveiling distinct exceptional entanglement phenomena, exemplified by an entanglement transition, occurring at the exceptional point (EP) of NH interacting quantum systems. We illustrate and demonstrate such purely quantum-mechanical NH effects with a naturally-dissipative light-matter system, engineered in a circuit quantum electrodynamics architecture. Our results lay the foundation for studies of genuinely quantum-mechanical NH physics, signified by EP-enabled entanglement behaviors.

Published
2022
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32. External control of qubit-photon interaction and multi-qubit reset in a dissipative quantum network

Author

National Natural Science Foundation of China, Natural Science Foundation of Fujian Province, Beijing Institute of Technology, National Key Research and Development Program (China), Zhang, Xian-Peng, Shen, Li-Tuo, Zhang, Yuan, Wu, Huaizhi, Yang, Zhen-Biao, Yin, Zhang-Qi, National Natural Science Foundation of China, Natural Science Foundation of Fujian Province, Beijing Institute of Technology, National Key Research and Development Program (China), Zhang, Xian-Peng, Shen, Li-Tuo, Zhang, Yuan, Wu, Huaizhi, Yang, Zhen-Biao, and Yin, Zhang-Qi

Abstract

A quantum network is a promising quantum many-body system because of its tailored geometry and controllable interaction. Here, we propose an external control scheme for the qubit-photon interaction and multiqubit reset in a dissipative quantum network, which comprises superconducting circuit chains with microwave drives and filter-filter couplings. The traditional multiqubit reset of the quantum network requires physically disconnected qubits to prevent their entanglement. However, we use an original effect of dissipation, i.e., consuming the entanglement generated by qubits’ interaction, to achieve an external control of the multiqubit reset in an always-connected superconducting circuit. The reset time is independent of the number of qubits in the quantum network. Our proposal can tolerate considerable fluctuations in the system parameters and can be applicable to higher-dimensional quantum networks.

Published
2021

47. Modulated Charge Injection in p-Type Dye-Sensitized Solar Cells Using Fluorene-Based Light Absorbers

Author

Liu, Zonghao, primary, Xiong, Dehua, additional, Xu, Xiaobao, additional, Arooj, Qudsia, additional, Wang, Huan, additional, Yin, Liyuan, additional, Li, Wenhui, additional, Wu, Huaizhi, additional, Zhao, Zhixin, additional, Chen, Wei, additional, Wang, Mingkui, additional, Wang, Feng, additional, Cheng, Yi-Bing, additional, and He, Hongshan, additional

Published
2014
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