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20 results on '"Lu, Xingda"'

1. Continuous field tracking with machine learning and steady state spin squeezing

Author

Duan, Junlei, Hu, Zhiwei, Lu, Xingda, Xiao, Liantuan, Jia, Suotang, Mølmer, Klaus, and Xiao, Yanhong

Subjects
Quantum Physics
Abstract

Entanglement plays a crucial role in proposals for quantum metrology, yet demonstrating quantum enhancement in sensing with sustained spin entanglement remains a challenging endeavor. Here, we combine optical pumping and continuous quantum nondemolition measurements to achieve a sustained spin squeezed state with $\bm{4 \times 10^{10}}$ hot atoms. A metrologically relevant steady state squeezing of $\bm{-3.23 \pm 0.24}$ dB using prediction and retrodiction is maintained for about one day. We employ the system to track different types of continuous time-fluctuating magnetic fields, where we construct deep learning models to decode the measurement records from the optical signals. Quantum enhancement due to the steady spin squeezing is verified in our atomic magnetometer. These results represent important progress towards applying long-lived quantum entanglement resources in realistic settings.

Published
2024

2. Topological atomic spinwave lattices by dissipative couplings

Author

Hao, Dongdong, Wang, Lin, Lu, Xingda, Cao, Xuzhen, Jia, Suotang, Hu, Ying, and Xiao, Yanhong

Subjects
Quantum Physics
Abstract

Recent experimental advance in creating dissipative couplings provides a new route for engineering exotic lattice systems and exploring topological dissipation. Using the spatial lattice of atomic spinwaves in a vacuum vapor cell, where purely dissipative couplings arise from diffusion of atoms, we experimentally realize a dissipative version of the Su-Schrieffer-Heeger (SSH) model. We construct the dissipation spectrum of the topological or trivial lattices via electromagnetically-induced-transparency (EIT) spectroscopy. The topological dissipation spectrum is found to exhibit edge modes within a dissipative gap. We validate chiral symmetry of the dissipative SSH couplings, and also probe topological features of the generalized dissipative SSH model. This work paves the way for realizing non-Hermitian topological quantum optics via dissipative couplings., Comment: 6 pages, 4 figures

Published
2022
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3. Non-reciprocity and quantum correlations of light transport in hot atoms via reservoir engineering

Author

Lu, Xingda, Cao, Wanxia, Yi, Wei, Shen, Heng, and Xiao, Yanhong

Subjects
Quantum Physics
Abstract

The breaking of reciprocity is a topic of great interest in fundamental physics and optical information processing applications. We demonstrate non-reciprocal light transport in a quantum system of hot atoms by engineering the dissipative atomic reservoir. Our scheme is based on the phase-sensitive light transport in a multi-channel photon-atom interaction configuration, where the phase of collective atomic excitations is tunable through external driving fields. Remarkably, we observe inter-channel quantum correlations which originate from interactions with the judiciously engineered reservoir. The non-reciprocal transport in a quantum optical atomic system constitutes a new paradigm for atom-based, non-reciprocal optics, and offers opportunities for quantum simulations with coupled optical channels.

Published
2021
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4. Quantum correlations near the exceptional point

Author

Cao, Wanxia, Lu, Xingda, Meng, Xin, Sun, Jian, Shen, Heng, and Xiao, Yanhong

Subjects
Quantum Physics
Abstract

Recent advances in non-Hermitian physical systems have led to numerous novel optical phenomena and applications. However, most realizations are limited to classical systems and quantum fluctuations of light is unexplored. For the first time, we report the observation of quantum correlations between light channels in an anti-symmetric optical system made of flying atoms. Two distant optical channels coupled dissipatively, display gain, phase sensitivity and quantum correlations with each other, even under linear atom-light interaction within each channel. We found that quantum correlations emerge in the phase unbroken regime and disappears after crossing the exceptional point. Our microscopic model considering quantum noise evolution produces results in good qualitative agreement with experimental observations. This work opens up a new direction of experimental quantum nonlinear optics using non-Hermitian systems, and demonstrates the viability of nonlinear coupling with linear systems by using atomic motion as feedback.

Published
2019
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5. Measurements with prediction and retrodiction on the collective spin of 10^{11} atoms beat the standard quantum limit

Author

Bao, Han, Duan, Junlei, Lu, Xingda, Li, Pengxiong, Qu, Weizhi, Jin, Shenchao, Wang, Mingfeng, Novikova, Irina, Mikhailov, Eugeniy, Zhao, Kai-Feng, Mølmer, Klaus, Shen, Heng, and Xiao, Yanhong

Subjects
Quantum Physics
Abstract

Quantum probes using $N$ uncorrelated particles give a limit on the measurement sensitivity referred to as the standard quantum limit (SQL). The SQL, however, can be overcome by exploiting quantum entangled states, such as spin squeezed states. We report generation of a quantum state, that surpasses the SQL for probing of the collective spin of $10^{11}$ $\text{Rb}$ atoms contained in a vapor cell. The state is prepared and verified by sequences of stroboscopic quantum non-demolition (QND) measurements, and we apply the theory of past quantum states to obtain the spin state information from the outcomes of both earlier and later QND measurements. In this way, we obtain a conditional noise reduction of 5.6 dB, and a metrologically-relevant squeezing of $4.5\pm0.40~\text{dB}$. The past quantum state yields tighter information on the spin component than we can obtain by a conventional QND measurement. Our squeezing results are obtained with 1000 times more atoms than in any previous experiments with a corresponding record $4.6\times10^{-13} rad^2$ variance of the angular fluctuations of a squeezed collective spin., Comment: 5 pages,3 figures

Published
2018
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6. Spin squeezing of 10.sup.11 atoms by prediction and retrodiction measurements

Author

Bao, Han, Duan, Junlei, Jin, Shenchao, Lu, Xingda, Li, Pengxiong, Qu, Weizhi, and Wang, Mingfeng

Subjects
Atoms -- Measurement, Rubidium -- Atomic properties -- Methods -- Measurement, Particle spin -- Methods -- Measurement, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

The measurement sensitivity of quantum probes using N uncorrelated particles is restricted by the standard quantum limit.sup.1, which is proportional to [Formula omitted]. This limit, however, can be overcome by exploiting quantum entangled states, such as spin-squeezed states.sup.2. Here we report the measurement-based generation of a quantum state that exceeds the standard quantum limit for probing the collective spin of 10.sup.11 rubidium atoms contained in a macroscopic vapour cell. The state is prepared and verified by sequences of stroboscopic quantum non-demolition (QND) measurements. We then apply the theory of past quantum states.sup.3,4 to obtain spin state information from the outcomes of both earlier and later QND measurements. Rather than establishing a physically squeezed state in the laboratory, the past quantum state represents the combined system information from these prediction and retrodiction measurements. This information is equivalent to a noise reduction of 5.6 decibels and a metrologically relevant squeezing of 4.5 decibels relative to the coherent spin state. The past quantum state yields tighter constraints on the spin component than those obtained by conventional QND measurements. Our measurement uses 1,000 times more atoms than previous squeezing experiments.sup.5-10, with a corresponding angular variance of the squeezed collective spin of 4.6 × 10.sup.-13 radians squared. Although this work is rooted in the foundational theory of quantum measurements, it may find practical use in quantum metrology and quantum parameter estimation, as we demonstrate by applying our protocol to quantum enhanced atomic magnetometry. A squeezed collective state of 10.sup.11 rubidium atoms is generated by quantum non-demolition measurements, and the accuracy of the estimation of their collective spin is improved using past quantum state retrodiction., Author(s): Han Bao [sup.1] , Junlei Duan [sup.1] , Shenchao Jin [sup.1] , Xingda Lu [sup.1] , Pengxiong Li [sup.1] , Weizhi Qu [sup.1] , Mingfeng Wang [sup.1] [sup.2] , [...]

Published
2020
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8. Versatile roles of polyamines in improving abiotic stress tolerance of plants

Author

Shao, Jinhua, primary, Huang, Kai, additional, Batool, Maria, additional, Idrees, Fahad, additional, Afzal, Rabail, additional, Haroon, Muhammad, additional, Noushahi, Hamza Armghan, additional, Wu, Weixiong, additional, Hu, Qiliang, additional, Lu, Xingda, additional, Huang, Guoqin, additional, Aamer, Muhammad, additional, Hassan, Muhammad Umair, additional, and El Sabagh, Ayman, additional

Published
2022
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12. Spin-squeezing by prediction and retrodiction measurements: beyond the Heisenberg uncertainty relation

Author

Bao, Han, primary, Jin, Shenchao, additional, Duan, Junlei, additional, Lu, Xingda, additional, Li, Pengxiong, additional, Qu, Weizhi, additional, Wang, Mingfeng, additional, Novikova, Irina, additional, Mikhailov, Eugeniy, additional, Zhao, Kaifeng, additional, Jia, Suotang, additional, Mølmer, Klaus, additional, Shen, Heng, additional, and Xiao, Yanhong, additional

Published
2021
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15. The optimization design for a diamond window in W band TWT

Author

Gao Zhiqiang, Pengchao Huang, Wang Hui, Zhou Zhilong, Liu Yingbo, Liu Qiang, Song Zechun, and Lu Xingda

Subjects
business.industry, A diamond, Window (computing), Dielectric, Conductivity, computer.software_genre, Simulation software, Software, Optics, W band, Optoelectronics, Dielectric loss, business, computer
Abstract

This paper introduces the design of a diamond window. By using CST simulation software, calculation results are given. This kind of window has important significances for the characteristic improvement of W band TWT.

Published
2015
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16. Spin squeezing of 1011atoms by prediction and retrodiction measurements

Author

Bao, Han, Duan, Junlei, Jin, Shenchao, Lu, Xingda, Li, Pengxiong, Qu, Weizhi, Wang, Mingfeng, Novikova, Irina, Mikhailov, Eugeniy E., Zhao, Kai-Feng, Mølmer, Klaus, Shen, Heng, and Xiao, Yanhong

Abstract

The measurement sensitivity of quantum probes using Nuncorrelated particles is restricted by the standard quantum limit1, which is proportional to 1/N. This limit, however, can be overcome by exploiting quantum entangled states, such as spin-squeezed states2. Here we report the measurement-based generation of a quantum state that exceeds the standard quantum limit for probing the collective spin of 1011rubidium atoms contained in a macroscopic vapour cell. The state is prepared and verified by sequences of stroboscopic quantum non-demolition (QND) measurements. We then apply the theory of past quantum states3,4to obtain spin state information from the outcomes of both earlier and later QND measurements. Rather than establishing a physically squeezed state in the laboratory, the past quantum state represents the combined system information from these prediction and retrodiction measurements. This information is equivalent to a noise reduction of 5.6 decibels and a metrologically relevant squeezing of 4.5 decibels relative to the coherent spin state. The past quantum state yields tighter constraints on the spin component than those obtained by conventional QND measurements. Our measurement uses 1,000 times more atoms than previous squeezing experiments5–10, with a corresponding angular variance of the squeezed collective spin of 4.6 × 10−13radians squared. Although this work is rooted in the foundational theory of quantum measurements, it may find practical use in quantum metrology and quantum parameter estimation, as we demonstrate by applying our protocol to quantum enhanced atomic magnetometry.

Published
2020
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18. A two-stage process for the production of a novel cheese flavor powder

Author

Ma, Xiaolei, Wang, Jianming, Lu, Xingda, Qiao, Changsheng, Ma, Xiaolei, Wang, Jianming, Lu, Xingda, and Qiao, Changsheng

Abstract

A novel method to produce cheese flavor powder by combination mold fermentation and enzyme acceleration was developed. In this research, Actinomucor elegans was selected to ferment the milk. The optimum conditions for fermentation were 220 rpm, at the temperature 29C and for 2 days. In order to accelerate the flavor formation, the effects of lipase and protease to fermented milk were also investigated. According to the sensory evaluation scores, as well as the degree of hydrolysis, the optimum formula of enzymes were Palatase 2000 L 2‰ (m/v) and proteases 1‰ (m/v), proteases was prepared by mixing 2:1 (m/m) proportion of Flavourzyme 500MG and Neutrase 1.5MG. The optimum conditions for enzymolysis were 50C, 6.5 (initial pH) and 6 h (enzymolysis time), and the product of optimum process was tested by gas chromatography-mass spectrometry (GC-MS). According to the sensory evaluation result and GC-MS, the novel cheese flavor powder showed superior profile for its intensity and flavorful. Practical Application Cheese production has been considered as an important raw material of some food because of its great aroma and flavor. The novel cheese flavor powder is a product retaining the strong aroma and flavor of cheese, namely, creamy, odor, sour and pungent. The cheese flavor powder is mainly used as a spice in culinary preparations for imparting a characteristic cheese flavor. The product is generally light yellow in color and is stable in quality because of mealy structure and low moisture content. It is a ready-to-use preparation, which can be used in homes, restaurants and institutional catering. The development of novel cheese flavor powder with richer flavor, lighter weight and ease of use may be governed by a mass of customer favorite. © 2013 Wiley Periodicals, Inc.

Published
2013

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