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18 results on '"Jin Shenchao"'

1. Concurrent spin squeezing and light squeezing in an atomic ensemble

Author

Jin, Shenchao, Duan, Junlei, Zhang, Youwei, Zhang, Xichang, Bao, Han, Shen, Heng, Xiao, Liantuan, Jia, Suotang, Wang, Mingfeng, and Xiao, Yanhong

Subjects
Quantum Physics
Abstract

Squeezed spin states and squeezed light are both key resources for quantum metrology and quantum information science, but have been separately investigated in experiments so far. Simultaneous generation of these two types of quantum states in one experiment setup is intriguing but remains a challenging goal. Here we propose a novel protocol based on judiciously engineered symmetric atom-light interaction, and report proof-of-principle experimental results of concurrent spin squeezing of $0.61\pm0.09~\mathrm{dB}$ and light squeezing of $0.65^{+0.11}_{-0.10}~\mathrm{dB}$ in a hot atomic ensemble. The squeezing process is deterministic, yielding fixed squeezing directions for both the light field and the collective atomic spin. Furthermore, the squeezed light modes lie in the multiple frequency sidebands of a single spatial mode. This new type of dual squeezed state is applicable for quantum enhanced metrology and quantum networks. Our method can be extended to other quantum platforms such as optomechanics, cold atom and trapped ions., Comment: manuscript with 7 pages, 4 figures, supplemental material with 17 pages, 9 figures

Published
2023
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2. Machine Learning Assisted Vector Atomic Magnetometry

Author

Meng, Xin, Zhang, Youwei, Zhang, Xichang, Jin, Shenchao, Wang, Tingran, Jiang, Liang, Xiao, Liantuan, Jia, Suotang, and Xiao, Yanhong

Subjects
Physics - Instrumentation and Detectors, Physics - Optics
Abstract

We propose a novel paradigm to vector magnetometry based on machine learning. Unlike conventional schemes where one measured signal explicitly connects to one parameter, here we encode the three-dimensional magnetic-field information in the set of four simultaneously acquired signals, i.e., the oscillating optical rotation signal's harmonics of a frequency modulated laser beam traversing the atomic sample. The map between the recorded signals and the vectorial field information is established through a pre-trained deep neural network. We demonstrate experimentally a single-shot all optical vector atomic magnetometer, with a simple scalar-magnetometer design employing only one elliptically-polarized laser beam and no additional coils. Magnetic field amplitude sensitivities of about 100 $\textrm{fT}/\sqrt{\textrm{Hz}}$ and angular sensitivities of about 100 $\mu rad/\sqrt{\textrm{Hz}}$ (for a magnetic field of about 140 nT) are derived from the neural network. Our approach can reduce the complexity of the architecture of vector magnetometers, and may shed light on the general design of multiparameter sensing., Comment: 8 pages,4 figures

Published
2022

4. Retrodiction beyond the Heisenberg uncertainty relation

Author

Bao, Han, Jin, Shenchao, Duan, Junlei, Jia, Suotang, Mølmer, Klaus, Shen, Heng, and Xiao, Yanhong

Subjects
Quantum Physics
Abstract

In quantum mechanics, the Heisenberg uncertainty relation presents an ultimate limit to the precision by which one can predict the outcome of position and momentum measurements on a particle. Heisenberg explicitly stated this relation for the prediction of "hypothetical future measurements", and it does not describe the situation where knowledge is available about the system both earlier and later than the time of the measurement. We study what happens under such circumstances with an atomic ensemble containing $10^{11}$ $^{87}\text{Rb}$ atoms, initiated nearly in the ground state in presence of a magnetic field. The collective spin observables of the atoms are then well described by canonical position and momentum observables, $\hat{x}_A$ and $\hat{p}_A$ that satisfy $[\hat{x}_A,\hat{p}_A]=i\hbar$. Quantum non-demolition measurements of $\hat{p}_A$ before and of $\hat{x}_A$ after time $t$ allow precise estimates of both observables at time $t$. The capability of assigning precise values to multiple observables and to observe their variation during physical processes may have implications in quantum state estimation and sensing., Comment: 10 pages,4 figures

Published
2020
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5. Sub-Hertz resonance by weak measurement

Author

Qu, Weizhi, Sun, Jian, Jin, Shenchao, Jiang, Liang, Wen, Jianming, and Xiao, Yanhong

Subjects
Physics - Atomic Physics, Quantum Physics
Abstract

Weak measurement (WM) with state pre- and post-selection can amplify otherwise undetectable small signals and thus promise great potentials in precision measurements. Although frequency measurements offer the hitherto highest precision owing to stable narrow atomic transitions, it remains a long-standing interest to develop new schemes to further escalate their performance. Here, we propose and demonstrate a WM-enhanced spectroscopy technique which is capable of narrowing the resonance to 0.1 Hz in a room-temperature atomic vapor cell. Potential of this technique for precision measurement is demonstrated through weak magnetic field sensing. By judiciously pre- and post-selecting frequency-modulated input and output optical states in a nearly-orthogonal manner, a sensitivity of $\text{7 fT/}\sqrt{\text{Hz}}$ near DC is achieved, using only one laser beam of $\text{7 }\text{\mu W}$ power. Additionally, our results extend the WM framework to a non-Hermitian Hamiltonian, and shed new light in metrology and bio-magnetic field sensing applications., Comment: 11 pages, 5 figures

Published
2018

6. 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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7. 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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11. 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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12. Indentation Creep Behaviors of SnSb8Cu4 Babbitt Alloy with Zn and Cu Addition.

Author

Song Zhenya, Jin Shenchao, Shen Yueming, Teng Jiabin, Lu Bing, and Zhang Lincai

Subjects
ALLOYS, STRAINS & stresses (Mechanics), CRYSTAL grain boundaries, TIN, COPPER, COPPER-zinc alloys
Abstract

In the present study, the effects of copper and zinc addition on the microstructure and indentation creep behaviors of SnSb8Cu4 Babbitt alloy were systematically investigated. An indentation creep testing device with a flat tip indenter was used to characterize the creep behaviors of the Babbitt alloys at ~100°C with different loads. By increasing the copper content from 4wt% to 8wt%, coarser and shorter Cu6Sn5 dendrites with larger volume fraction were observed. The corresponding Brinell hardness increased from 21.9 to 28.1 at room temperature. However, the improvement in creep resistance was not obvious. After adding 0.72 wt% zinc, large number of small-sized SnSb particles precipitated along the grain boundaries of tin matrix. The total volume fraction of intermetallics, i.e., Cu6Sn5 and SnSb particles, increased from 15.1% to 20.9%. Although, the increment of Brinell hardness was not remarkable at room temperature, dramatic improvement in creep resistance was observed. The addition of zinc caused the decrement of the solid solubility of Sb in tin matrix, while more network-like SnSb particles precipitating in tin matrix were found, giving rise to the pinning effect against grain boundary sliding during creep deformation. However, increment of copper content showed no obvious effect on the solid solubility of Sb in tin matrix. Meanwhile, an exponential relationship between indentation creep rate and indentation stress at the steady creep stage was found. Based on the measured data, the indentation stress exponent of SnSb8Cu4, SnSb8Cu8 and SnSb8Cu4Zn was deduced to be 2.949, 2.865 and 2.743, respectively. [ABSTRACT FROM AUTHOR]

Published
2022
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15. Effect of heat treatments on the microstructure and mechanical properties of Zn-15 wt% Al alloy

Author

Zhenya Song, Shi Tiesheng, Yong Liu, Yan Ming, Jin Shenchao, Yanbiao Ren, and Lincai Zhang

Subjects
Biomaterials, Materials science, Polymers and Plastics, Alloy, Metallurgy, Metals and Alloys, engineering, engineering.material, Microstructure, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Annealing (glass)
Abstract

The effect of heat treatment on the micro-structural and mechanical properties of Zn-15wt%Al alloys was investigated systematically in this work. After being annealed below 275 °C, granular α particles were distributed homogeneously in the η phase matrix, while a lamellar microstructure along with isolated η grains was observed when the alloys were annealed above 275 °C, followed by an air cooling (AC) treatment. A subsequent tensile test showed that the strength of alloys always increased with the annealing temperature. However, when the alloys were annealed above 275 °C, followed by a water-quenched (WQ) treatment, their strength firstly decreased with the aging time and then became unchanged. It was revealed by an in situ investigation that the γ′ phase retained from quenching decomposed gradually into an equiaxed microstructure during aging, leading to a reduction in the strength. Transmission electron microscopic (TEM) studies showed that dislocations were rarely inspected after a severely plastic deformation in the WQ-treated alloys, indicating that grain boundary sliding and rotation would be a dominant deformation mechanism. However, for the AC-treated alloys, dislocation tangles were easily found in lamellas due to the severe plastic deformations, demonstrating that in addition to grain boundary sliding and rotation, dislocation slip was another important deformation mechanism. A strength model, incorporating phase transformation dynamics with the law of mixtures, was established for the WQ-treated alloys annealed above 275 °C. Meanwhile, the number of α particles in the γ′ phase was assumed to be a key parameter for understanding the evolution of mechanical properties of Zn-15wt%Al alloys during the heat treatments. The more α particles in a unit volume of the γ′ phase, the easier plastic deformation the alloys is prone to, a lower strength and a larger elongation of the alloys will be.

Published
2020
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17. 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. Concurrent Spin Squeezing and Light Squeezing in an Atomic Ensemble.

Author

Jin S, Duan J, Zhang Y, Zhang X, Bao H, Shen H, Xiao L, Jia S, Wang M, and Xiao Y

Abstract

Squeezed spin states and squeezed light are both key resources for quantum metrology and quantum information science, but have been separately investigated in experiments so far. Simultaneous generation of these two types of quantum states in one experiment setup is intriguing but remains a challenging goal. Here, we propose a novel protocol based on judiciously engineered symmetric atom-light interaction, and report proof-of-principle experimental results of concurrent spin squeezing of 0.61±0.09  dB and light squeezing of 0.65_{-0.10}^{+0.11}  dB in a hot atomic ensemble. The squeezing process is deterministic, yielding fixed squeezing directions for both the light field and the collective atomic spin. Furthermore, the squeezed light modes lie in the multiple frequency sidebands of a single spatial mode. This new type of dual squeezed state is applicable for quantum enhanced metrology and quantum networks. Our method can be extended to other quantum platforms such as optomechanics, cold atoms, and trapped ions.

Published
2024
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