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26 results on '"Long, Xinyue"'

1. Self-Consistent Determination of Single-Impurity Anderson Model Using Hybrid Quantum-Classical Approach on a Spin Quantum Simulator

Author

Nie, Xinfang, Zhu, Xuanran, Fan, Yu-ang, Long, Xinyue, Liu, Hongfeng, Huang, Keyi, Xi, Cheng, Che, Liangyu, Zheng, Yuxuan, Feng, Yufang, Yang, Xiaodong, and Lu, Dawei

Subjects
Quantum Physics
Abstract

The accurate determination of the electronic structure of strongly correlated materials using first principle methods is of paramount importance in condensed matter physics, computational chemistry, and material science. However, due to the exponential scaling of computational resources, incorporating such materials into classical computation frameworks becomes prohibitively expensive. In 2016, Bauer et al. proposed a hybrid quantum-classical approach to correlated materials Phys. Rev. X 6, 031045 (2016)}] that can efficiently tackle the electronic structure of complex correlated materials. Here, we experimentally demonstrate that approach to tackle the computational challenges associated with strongly correlated materials. By seamlessly integrating quantum computation into classical computers, we address the most computationally demanding aspect of the calculation, namely the computation of the Green's function, using a spin quantum processor. Furthermore, we realize a self-consistent determination of the single impurity Anderson model through a feedback loop between quantum and classical computations. A quantum phase transition in the Hubbard model from the metallic phase to the Mott insulator is observed as the strength of electron correlation increases. As the number of qubits with high control fidelity continues to grow, our experimental findings pave the way for solving even more complex models, such as strongly correlated crystalline materials or intricate molecules., Comment: 6 pages + appendices

Published
2024
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2. Experimental Realization of Self-Contained Quantum Refrigeration

Author

Huang, Keyi, Xi, Cheng, Long, Xinyue, Liu, Hongfeng, Fan, Yu-ang, Wang, Xiangyu, Zheng, Yuxuan, Feng, Yufang, Nie, Xinfang, and Lu, Dawei

Subjects
Quantum Physics
Abstract

A fundamental challenge in quantum thermodynamics is the exploration of inherent dimensional constraints in thermodynamic machines. In the context of two-level systems, the most compact refrigerator necessitates the involvement of three entities, operating under self-contained conditions that preclude the use of external work sources. Here, we build such a smallest refrigerator using a nuclear spin system, where three distinct two-level carbon-13 nuclei in the same molecule are involved to facilitate the refrigeration process. The self-contained feature enables it to operate without relying on net external work, and the unique mechanism sets this refrigerator apart from its classical counterparts. We evaluate its performance under varying conditions and systematically scrutinize the cooling constraints across a spectrum of scenarios, which sheds light on the interplay between quantum information and thermodynamics., Comment: 6 pages + appendices

Published
2024
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3. Recovering optimal precision in quantum sensing using imperfect control

Author

Li, Zi-Shen, Long, Xinyue, Yang, Xiaodong, Lu, Dawei, and Yang, Yuxiang

Subjects
Quantum Physics
Abstract

Quantum control plays a crucial role in enhancing precision scaling for quantum sensing. However, most existing protocols require perfect control, even though real-world devices inevitably have control imperfections. Here, we consider a fundamental setting of quantum sensing with imperfect clocks, where the duration of control pulses and the interrogation time are all subject to uncertainty. Under this scenario, we investigate the task of frequency estimation in the presence of a non-Markovian environment. We design a control strategy and prove that it outperforms any control-free strategies, recovering the optimal Heisenberg scaling up to a small error term that is intrinsic to this model. We further demonstrate the advantage of our control strategy via experiments on a nuclear magnetic resonance (NMR) platform. Our finding confirms that the advantage of quantum control in quantum sensing persists even in the presence of imperfections., Comment: 18 pages, 7 figures

Published
2024

4. Experimental Validation of Enhanced Information Capacity by Quantum Switch in Accordance with Thermodynamic Laws

Author

Xi, Cheng, Liu, Xiangjing, Liu, Hongfeng, Huang, Keyi, Long, Xinyue, Ebler, Daniel, Nie, Xinfang, Dahlsten, Oscar, and Lu, Dawei

Subjects
Quantum Physics
Abstract

We experimentally probe the interplay of the quantum switch with the laws of thermodynamics. The quantum switch places two channels in a superposition of orders and may be applied to thermalizing channels. Quantum-switching thermal channels has been shown to give apparent violations of the second law. Central to these apparent violations is how quantum switching channels can increase the capacity to communicate information. We experimentally show this increase and how it is consistent with the laws of thermodynamics, demonstrating how thermodynamic resources are consumed. We use a nuclear magnetic resonance approach with coherently controlled interactions of nuclear spin qubits. We verify an analytical upper bound on the increase in capacity for channels that preserve energy and thermal states, and demonstrate that the bound can be exceeded for an energy-altering channel. We show that the switch can be used to take a thermal state to a state that is not thermal, whilst consuming free energy associated with the coherence of a control system. The results show how the switch can be incorporated into quantum thermodynamics experiments as an additional resource., Comment: 6 pages, 4 figures. Comments are welcome!

Published
2024
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7. Control-enhanced quantum metrology under Markovian noise

Author

Zhai, Yue, Yang, Xiaodong, Tang, Kai, Long, Xinyue, Nie, Xinfang, Xin, Tao, Lu, Dawei, and Li, Jun

Subjects
Quantum Physics
Abstract

Quantum metrology is supposed to significantly improve the precision of parameter estimation by utilizing suitable quantum resources. However, the predicted precision can be severely distorted by realistic noises. Here, we propose a control-enhanced quantum metrology scheme to defend against these noises for improving the metrology performance. Our scheme can automatically alter the parameter encoding dynamics with adjustable controls, thus leading to optimal resultant states that are less sensitive to the noises under consideration. As a demonstration, we numerically apply it to the problem of frequency estimation under several typical Markovian noise channels. Through comparing our control-enhanced scheme with the standard scheme and the ancilla-assisted scheme, we show that our scheme performs better and can improve the estimation precision up to around one order of magnitude. Furthermore, we conduct a proof-of-principle experiment in nuclear magnetic resonance system to verify the effectiveness of the proposed scheme. The research here is helpful for current quantum platforms to harness the power of quantum metrology in realistic noise environments., Comment: 9 pages, 5 figures

Published
2022
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8. Experimental realization of a topologically protected Hadamard gate via braiding Fibonacci anyons

Author

Fan, Yu-ang, Li, Yingcheng, Hu, Yuting, Li, Yishan, Long, Xinyue, Liu, Hongfeng, Yang, Xiaodong, Nie, Xinfang, Li, Jun, Xin, Tao, Lu, Dawei, and Wan, Yidun

Subjects
Quantum Physics
Abstract

Topological quantum computation (TQC) is one of the most striking architectures that can realize fault-tolerant quantum computers. In TQC, the logical space and the quantum gates are topologically protected, i.e., robust against local disturbances. The topological protection, however, requires rather complicated lattice models and hard-to-manipulate dynamics; even the simplest system that can realize universal TQC--the Fibonacci anyon system--lacks a physical realization, let alone braiding the non-Abelian anyons. Here, we propose a disk model that can realize the Fibonacci anyon system, and construct the topologically protected logical spaces with the Fibonacci anyons. Via braiding the Fibonacci anyons, we can implement universal quantum gates on the logical space. Our proposal is platform-independent. As a demonstration, we implement a topological Hadamard gate on a logical qubit through a sequence of $15$ braiding operations of three Fibonacci anyons with merely $2$ nuclear spin qubits. The gate fidelity reaches 97.18% by randomized benchmarking. We further prove by experiment that the logical space and Hadamard gate are topologically protected: local disturbances due to thermal fluctuations result in a global phase only. Our work is a proof of principle of TQC and paves the way towards fault-tolerant quantum computation., Comment: 8 pages, 4 figures

Published
2022

9. Entanglement-Enhanced Quantum Metrology in Colored Noise by Quantum Zeno Effect

Author

Long, Xinyue, He, Wan-Ting, Zhang, Na-Na, Tang, Kai, Lin, Zidong, Liu, Hongfeng, Nie, Xinfang, Feng, Guanru, Li, Jun, Xin, Tao, Ai, Qing, and Lu, Dawei

Subjects
Quantum Physics, Physics - Atomic Physics, Physics - Optics
Abstract

In open quantum systems, the precision of metrology inevitably suffers from the noise. {In Markovian open quantum dynamics, the precision can not be improved by using entangled probes although the measurement time is effectively shortened.} However, it was predicted over one decade ago that in a non-Markovian one, the error can be significantly reduced by the quantum Zeno effect (QZE) [Chin, Huelga, and Plenio, Phys. Rev. Lett. \textbf{109}, 233601 (2012)]. In this work, we apply a recently-developed quantum simulation approach to experimentally verify that entangled probes can improve the precision of metrology by the QZE. Up to $n=7$ qubits, we demonstrate that the precision has been improved by a factor of $n^{1/4}$, which is consistent with the theoretical prediction. Our quantum simulation approach may provide an intriguing platform for experimental verification of various quantum metrology schemes., Comment: 6 pages, 4 figures

Published
2022
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10. Experimental quantum simulation of non-Hermitian dynamical topological states using stochastic Schr\'odinger equation

Author

Lin, Zidong, Zhang, Lin, Long, Xinyue, Fan, Yu-ang, Li, Yishan, Tang, Kai, Li, Jun, Nie, XinFang, Xin, Tao, Liu, Xiong-Jun, and Lu, Dawei

Subjects
Quantum Physics
Abstract

Noise is ubiquitous in real quantum systems, leading to non-Hermitian quantum dynamics, and may affect the fundamental states of matter. Here we report in experiment a quantum simulation of the two-dimensional non-Hermitian quantum anomalous Hall (QAH) model using the nuclear magnetic resonance processor. Unlike the usual experiments using auxiliary qubits, we develop a stochastic average approach based on the stochastic Schr\"odinger equation to realize the non-Hermitian dissipative quantum dynamics, which has advantages in saving the quantum simulation sources and simplifies implementation of quantum gates. We demonstrate the stability of dynamical topology against weak noise, and observe two types of dynamical topological transitions driven by strong noise. Moreover, a region that the emergent topology is always robust regardless of the noise strength is observed. Our work shows a feasible quantum simulation approach for dissipative quantum dynamics with stochastic Schr\"odinger equation and opens a route to investigate non-Hermitian dynamical topological physics.

Published
2022
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12. Experimental Realization of a Quantum Refrigerator Driven by Indefinite Causal Orders

Author

Nie, Xinfang, Zhu, Xuanran, Huang, Keyi, Tang, Kai, Long, Xinyue, Lin, Zidong, Tian, Yu, Qiu, Chudan, Xi, Cheng, Yang, Xiaodong, Li, Jun, Dong, Ying, Xin, Tao, and Lu, Dawei

Subjects
Quantum Physics
Abstract

Indefinite causal order (ICO) is playing a key role in recent quantum technologies. Here, we experimentally study quantum thermodynamics driven by ICO on nuclear spins using the nuclear magnetic resonance system. We realize the ICO of two thermalizing channels to exhibit how the mechanism works, and show that the working substance can be cooled or heated albeit it undergoes thermal contacts with reservoirs of the same temperature. Moreover, we construct a single cycle of the ICO refrigerator based on the Maxwell's demon mechanism, and evaluate its performance by measuring the work consumption and the heat energy extracted from the low-temperature reservoir. Unlike classical refrigerators in which the coefficient of performance (COP) is perversely higher the closer the temperature of the high-temperature and low-temperature reservoirs are to each other, the ICO refrigerator's COP is always bounded to small values due to the non-unit success probability in projecting the ancillary qubit to the preferable subspace. To enhance the COP, we propose and experimentally demonstrate a general framework based on the density matrix exponentiation (DME) approach, as an extension to the ICO refrigeration. The COP is observed to be enhanced by more than three times with the DME approach. Our work demonstrates a new way for non-classical heat exchange, and paves the way towards construction of quantum refrigerators on a quantum system., Comment: 5 pages, 4 figures

Published
2020

14. Frequency Scanning Interferometry Multi-Channel Synchronous Ranging Based on Rapid Suppression of Doppler Error

Author

Zhou, Qiang, Wu, Tengfei, Long, Xinyue, Zeng, Zhoumo, and Zhu, Jigui

Abstract

Multi-channel synchronous distance measurement is of great significance for the structural network monitoring of large-scale equipment manufacturing. The precision, efficiency, flexibility of measurement directly impacts the operation quality in manufacturing. In this paper, we propose a multi-channel synchronous rapid absolute distance measurement (ADM) system based on frequency scanning interferometry (FSI). A dual-interferometer structure was presented, by introducing optical intensity splitting inside the measurement interferometer to expand channels, reducing the multi-channel system complexity and ensuring the unity of the traceability chain. The system employs dual-laser interferometric signals mixing after spectral segmentation to achieve rapid suppression of Doppler error during the transmission of optical signal, significantly avoiding complex digital signal processing time for interference-signal overlap and improving the efficiency. To validate the performance of the system, we have employed a simulation to verify the target distance extraction of 10 channels. Subsequently, we conducted distance measurement experiments in different vibration conditions utilizing retroreflectors as the targets. The experimental results demonstrate that the Doppler effect has been significantly suppressed, and the precision of the stationary target reaches 1 μm particularly, indicating that this system has high potential in application for high-precision structural monitoring.

Published
2024
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18. Enhanced broadband reflection properties of PSCLCs films supported by electrospun nanofiber networks loaded with Cs0.33WO3 nanoparticles.

Author

Long, Xinyue, Zhao, Yuzhen, Gao, Hong, Du, Zhuohong, Zhang, Huimin, Luan, Yi, Wang, Dong, and Li, Chunsheng

Subjects
*CHOLESTERIC liquid crystals, *NANOPARTICLES, *LIQUID crystals, *INFRARED equipment, *OLEIC acid, *OPTICAL properties
Abstract

The introduction of nanoparticles into cholesteric liquid crystals has long provided inspiration for innovative device materials. A novel material design strategy was demonstrated to achieve a broadband reflection of polymer-stabilised cholesteric liquid crystals (PSCLCs) based on Cs0.33WO3 nanoparticles and the polymer nanonetworks in the PSCLCs. Through the adjustment of nanoparticle and chiral dopant (C6M) concentrations and meticulous control of polymerisation conditions, an appropriate pitch gradient distribution was achieved in the polymer-stabilised cholesteric liquid crystals (PSCLCs). This was attained by striking a delicate balance between the polymerisation speed and chiral dopant diffusion rate, resulting in optimal PSCLCs optical properties. Modification of Cs0.33WO3 nanoparticles by oleic acid was successfully accomplished as confirmed by IR spectroscopy. SEM and EDS analyses further demonstrated the distribution of nanoparticles in the spun fibre film. Moreover, POM observations showed that liquid crystals with nanofiber networks maintained the planar texture and temperature stability. The prepared broadband reflective film opens an avenue towards developing the reflection bandwidth in the PSCLCs, essential for intelligent windows and infrared shielding devices. [ABSTRACT FROM AUTHOR]

Published
2024
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19. Broad-wave reflection of polymer-stabilised cholesterol liquid crystal with nanofibers doped magnetic nanoparticles.

Author

Lu, Yinfu, Zhao, Yuzhen, Long, Xinyue, Gao, Hong, Du, Zhuohong, Zhang, Huimin, Wang, Dong, and Li, Chunsheng

Subjects
LIQUID crystals, MAGNETIC nanoparticles, NANOFIBERS, MAGNETIC flux density, CHOLESTERIC liquid crystals, TRANSMISSION electron microscopy, POLYMER liquid crystals
Abstract

In this study, the polymer-stabilised cholesterol-based liquid crystal (PSCLC) films with broad-wave reflection were prepared via PVA nanofibers as carriers loaded with Fe3O4 nanoparticles. Fe3O4 nanoparticles have absorption properties in the UV region. When UV light is irradiated along the thickness of the liquid crystal cell, the resulting gradient distribution of UV light intensity induces a gradient distribution of spacing and thus a broad-wave reflection. Specifically, the effects of nanoparticles content loaded in nanofibers, magnetic field strength, polymerisation time and temperature, UV light intensity and polymerised monomer content were studied. The result shows that the proper contents of Fe3O4 nanoparticles and the polymerisation conditions have favourable impacts on the broad-wave reflection of PSCLC films. To clarify the mechanism of formed broad-wave reflection, the morphology of nanofibers was observed by scanning electron microscopy (SEM). The modification of nanoparticles was collected by transmission electron microscopy (TEM) and infrared spectroscopy. The texture of PSCLC films was observed by POM. The broad-wave reflection were measured by UV-Vis spectrophotometer. This strategy broadens the broad-wave reflection of PSCLC films from 300 nm to 476 nm increasing its application potential in UV shielding devices, and infrared thermal control devices. [ABSTRACT FROM AUTHOR]

Published
2024
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