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598 results on '"Wang, Huabing"'

1. Topological geometric frustration in a cube-surface artificial spin ice

Author

Yuan, Zixiong, Yue, Wen-Cheng, Huang, Peiyuan, Lyu, Yang-Yang, Dong, Sining, Dong, Ying, Wang, Huabing, Wu, Peiheng, and Wang, Yong-Lei

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Artificial spin ices provide a controlled platform for investigating diverse physical phenomena, such as geometric frustration, magnetic monopoles, and phase transitions, via deliberate design. Here, we introduce a novel approach by developing artificial spin ice on the surfaces of a three-dimensional cube, which leads to emergent geometric frustration mediated by topologically protected domain walls, distinct from its flat counterparts. These domain walls connect vertices at the corners of cube that acting as intrinsic topological defects. Utilizing Monte Carlo simulations, we observe robust, topologically protected correlations among the intrinsic topological defects, regardless of their spatial separation. Our findings demonstrate that three-dimensional surfaces can unveil emergent properties absent in flat architectures.

Published
2024
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3. Terahertz emission from mutually synchronized standalone Bi2Sr2CaCu2O8+x intrinsic-Josephson-junction stacks

Author

Wieland, Raphael, Kizilaslan, Olcay, Kinev, Nickolay, Dorsch, Eric, Guénon, Stefan, Song, Ziyu, Wei, Zihan, Wang, Huabing, Wu, Peiheng, Koelle, Dieter, Koshelets, Valery P., and Kleiner, Reinhold

Subjects
Condensed Matter - Superconductivity
Abstract

Suitably patterned single crystals made of the cuprate superconductor Bi$_2$Sr$_2$CaCu$_2$O$_{8+x}$ (BSCCO), intrinsically forming a stack of Josephson junctions, can generate electromagnetic radiation in the lower terahertz regime. Due to Joule heating the emission power of single stacks seems to be limited to values below 100 $\mu$W. To increase the radiation power, mutually synchronized arrays situated on the same BSCCO base crystal have been studied. Mutual electromagnetic interactions via a connecting BSCCO base crystal have been considered essential for synchronization, but the approach still suffers from Joule heating, preventing the synchronization of more than three stacks. In the present paper we show, on the basis of two emitting stacks, that mutual synchronization can also be achieved by stand-alone stacks contacted by gold layers and sharing only a common gold layer. Compared to BSCCO base crystals, the gold layers have a much higher thermal conductivity and their patterning is not very problematic. We analyze our results in detail, showing that the two oscillators exhibit phase correlations over a range of $\pm$0.4 GHz relative to their center frequencies, which we mainly studied between 745 GHz and 765 GHz. However, we also find that strong phase gradients in the beams radiated from both the mutually locked stacks and the unlocked ones play an important role and, presumably, diminish the detected emission power due to destructive interference. We speculate that the effect arises from higher-order cavity modes which are excited in the individual stacks. Our main message is that the mutual interaction provided by a common gold layer may open new possibilities for relaxing the Joule-heating-problem, allowing the synchronization of a higher number of stacks. Our findings may boost attempts to substantially increase the output power levels of the BSCCO terahertz oscillators.

Published
2024
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4. Magnetic nonreciprocity in a hybrid device of asymmetric artificial spin-ice-superconductors

Author

Li, Chong, Huang, Peiyuan, Wang, Chen-Guang, Li, Haojie, Lyu, Yang-Yang, Yue, Wen-Cheng, Yuan, Zixiong, Li, Tianyu, Tu, Xuecou, Tao, Tao, Dong, Sining, He, Liang, Jia, Xiaoqing, Sun, Guozhu, Kang, Lin, Wang, Huabing, Wu, Peiheng, and Wang, Yong-Lei

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics
Abstract

Controlling the size and distribution of potential barriers within a medium of interacting particles can unveil unique collective behaviors and innovative functionalities. In this study, we introduce a unique superconducting hybrid device using a novel artificial spin ice structure composed of asymmetric nanomagnets. This structure forms a distinctive superconducting pinning potential that steers unconventional motion of superconducting vortices, thereby inducing a magnetic nonreciprocal effect, in contrast to the electric nonreciprocal effect commonly observed in superconducting diodes. Furthermore, the polarity of the magnetic nonreciprocity is in-situ reversible through the tunable magnetic patterns of artificial spin ice. Our findings demonstrate that artificial spin ice not only precisely modulates superconducting characteristics but also opens the door to novel functionalities, offering a groundbreaking paradigm for superconducting electronics.

Published
2024
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5. Integrated and DC-powered superconducting microcomb

Author

Wang, Chen-Guang, Xu, Wuyue, Li, Chong, Shi, Lili, Jiang, Junliang, Guo, Tingting, Yue, Wen-Cheng, Li, Tianyu, Zhang, Ping, Lyu, Yang-Yang, Pan, Jiazheng, Deng, Xiuhao, Dong, Ying, Tu, Xuecou, Dong, Sining, Cao, Chunhai, Zhang, Labao, Jia, Xiaoqing, Sun, Guozhu, Kang, Lin, Chen, Jian, Wang, Yong-Lei, Wang, Huabing, and Wu, Peiheng

Subjects
Condensed Matter - Superconductivity, Physics - Applied Physics, Quantum Physics
Abstract

Frequency combs, specialized laser sources emitting multiple equidistant frequency lines, have revolutionized science and technology with unprecedented precision and versatility. Recently, integrated frequency combs are emerging as scalable solutions for on-chip photonics. Here, we demonstrate a fully integrated superconducting microcomb that is easy to manufacture, simple to operate, and consumes ultra-low power. Our turnkey apparatus comprises a basic nonlinear superconducting device, a Josephson junction, directly coupled to a superconducting microstrip resonator. We showcase coherent comb generation through self-started mode-locking. Therefore, comb emission is initiated solely by activating a DC bias source, with power consumption as low as tens of picowatts. The resulting comb spectrum resides in the microwave domain and spans multiple octaves. The linewidths of all comb lines can be narrowed down to 1 Hz through a unique coherent injection-locking technique. Our work represents a critical step towards fully integrated microwave photonics and offers the potential for integrated quantum processors.

Published
2024
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6. Tunable superconducting resonators via on-chip control of local magnetic field

Author

Wang, Chen-Guang, Yue, Wen-Cheng, Tu, Xuecou, Chi, Tianyuan, Guo, Tingting, Lyu, Yang-Yang, Dong, Sining, Cao, Chunhai, Zhang, Labao, Jia, Xiaoqing, Sun, Guozhu, Kang, Lin, Chen, Jian, Wang, Yong-Lei, Wang, Huabing, and Wu, Peiheng

Subjects
Condensed Matter - Superconductivity, Physics - Applied Physics
Abstract

Superconducting microwave resonators play a pivotal role in superconducting quantum circuits. The ability to fine-tune their resonant frequencies provides enhanced control and flexibility. Here, we introduce a frequency-tunable superconducting coplanar waveguide resonator. By applying electrical currents through specifically designed ground wires, we achieve the generation and control of a localized magnetic field on the central line of the resonator, enabling continuous tuning of its resonant frequency. We demonstrate a frequency tuning range of 54.85 MHz in a 6.21 GHz resonator. This integrated and tunable resonator holds great potential as a dynamically tunable filter and as a key component of communication buses and memory elements in superconducting quantum computing.

Published
2024
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7. Toroidic phase transitions in a direct-kagome artificial spin ice

Author

Yue, Wen-Cheng, Yuan, Zixiong, Huang, Peiyuan, Sun, Yizhe, Gao, Tan, Lyu, Yang-Yang, Tu, Xuecou, Dong, Sining, He, Liang, Dong, Ying, Cao, Xun, Kang, Lin, Wang, Huabing, Wu, Peiheng, Nisoli, Cristiano, and Wang, Yong-Lei

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Ferrotoroidicity, the fourth form of primary ferroic order, breaks both space and time inversion symmetry. So far, direct observation of ferrotoroidicity in natural materials remains elusive, which impedes the exploration of ferrotoroidic phase transitions. Here, we overcome the limitations of natural materials using an artificial nanomagnet system that can be characterized at the constituent level and at different effective temperatures. We design a nanomagnet array as to realize a direct-kagome spin ice. This artificial spin ice exhibits robust toroidal moments and a quasi-degenerate ground state with two distinct low-temperature toroidal phases: ferrotoroidicity and paratoroidicity. Using magnetic force microscopy and Monte Carlo simulation, we demonstrate a phase transition between ferrotoroidicity and paratoroidicity, along with a crossover to a non-toroidal paramagnetic phase. Our quasi-degenerate artificial spin ice in a direct-kagome structure provides a model system for the investigation of magnetic states and phase transitions that are inaccessible in natural materials.

Published
2024
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8. Unconventional superconducting diode effects via antisymmetry and antisymmetry breaking

Author

Li, Chong, Lyu, Yang-Yang, Yue, Wen-Cheng, Huang, Peiyuan, Li, Haojie, Li, Tianyu, Wang, Chen-Guang, Yuan, Zixiong, Dong, Ying, Ma, Xiaoyu, Tu, Xuecou, Tao, Tao, Dong, Sining, He, Liang, Jia, Xiaoqing, Sun, Guozhu, Kang, Lin, Wang, Huabing, Peeters, Francois M., Milošević, Milorad V., Wu, Peiheng, and Wang, Yong-Lei

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

Symmetry-breaking plays a pivotal role in unlocking intriguing properties and functionalities in material systems. For example, the breaking of spatial and temporal symmetries leads to a fascinating phenomenon of superconducting diode effect. However, generating and precisely controlling the superconducting diode effect poses significant challenges. Here, we take a novel route with deliberate manipulation of magnetic charge potentials to realize unconventional superconducting flux-quantum diode effects. We achieve this through suitably tailored nanoengineered arrays of nanobar magnets on top of a superconducting thin film. We demonstrate the vital roles of inversion antisymmetry and its breaking in evoking unconventional superconducting effects-a magnetically symmetric diode effect and an odd-parity magnetotransport effect. These effects are non-volatilely controllable through in-situ magnetization switching of the nanobar magnets. Our findings promote the use of antisymmetry (breaking) for initiating unconventional superconducting properties, paving the way for exciting prospects and innovative functionalities in superconducting electronics.

Published
2024
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10. Ultra-broadband near-field Josephson microwave microscopy

Author

Zhang, Ping, Lyu, Yang-Yang, Lv, Jingjing, Wei, Zihan, Chen, Shixian, Wang, Chenguang, Du, Hongmei, Li, Dingding, Wang, Zixi, Hou, Shoucheng, Su, Runfeng, Sun, Hancong, Du, Yuan, Du, Li, Gao, Liming, Wang, Yong-Lei, Wang, Huabing, and Wu, Peiheng

Subjects
Physics - Applied Physics, Condensed Matter - Superconductivity
Abstract

Advanced microwave technologies constitute the foundation of a wide range of modern sciences, including quantum computing, microwave photonics, spintronics, etc. To facilitate the design of chip-based microwave devices, there is an increasing demand for state-of-the-art microscopic techniques capable of characterizing the near-field microwave distribution and performance. In this work, we integrate Josephson junctions onto a nano-sized quartz tip, forming a highly sensitive microwave mixer on-tip. This allows us to conduct spectroscopic imaging of near-field microwave distributions with high spatial resolution. Leveraging its microwave-sensitive characteristics, our Josephson microscope achieves a broad detecting bandwidth of up to 200 GHz with remarkable frequency and intensity sensitivities. Our work emphasizes the benefits of utilizing the Josephson microscope as a real-time, non-destructive technique to advance integrated microwave electronics.

Published
2024

11. Tamm-cavity terahertz detector

Author

Tu, Xuecou, Zhang, Yichen, Zhou, Shuyu, Tang, Wenjing, Yan, Xu, Rui, Yunjie, Wang, Wohu, Yan, Bingnan, Zhang, Chen, Ye, Ziyao, Shi, Hongkai, Su, Runfeng, Wan, Chao, Dong, Daxing, Xu, Ruiying, Zhao, Qing-Yuan, Zhang, La-Bao, Jia, Xiao-Qing, Wang, Huabing, Kang, Lin, Chen, Jian, and Wu, Peiheng

Published
2024
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13. Study on the Data Storage Technology of Mini-Airborne Radar Based on Machine Learning

Author

Tian, Haishan, Yang, Qiong, Wang, Huabing, and Zhang, Jingke

Subjects
Computer Science - Hardware Architecture, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Systems and Control
Abstract

The data rate of airborne radar is much higher than the wireless data transfer rate in many detection applications, so the onboard data storage systems are usually used to store the radar data. Data storage systems with good seismic performance usually use NAND Flash as storage medium, and there is a widespread problem of long file management time, which seriously affects the data storage speed, especially under the limitation of platform miniaturization. To solve this problem, a data storage method based on machine learning is proposed for mini-airborne radar. The storage training model is established based on machine learning, and could process various kinds of radar data. The file management methods are classified and determined using the model, and then are applied to the storage of radar data. To verify the performance of the proposed method, a test was carried out on the data storage system of a mini-airborne radar. The experimental results show that the method based on machine learning can form various data storage methods adapted to different data rates and application scenarios. The ratio of the file management time to the actual data writing time is extremely low.

Published
2023

17. Crystallizing Kagome artificial spin ice

Author

Yue, Wen-Cheng, Yuan, Zixiong, Lyu, Yang-Yang, Dong, Sining, Zhou, Jian, Xiao, Zhi-Li, He, Liang, Tu, Xuecou, Dong, Ying, Wang, Huabing, Xu, Weiwei, Kang, Lin, Wu, Peiheng, Nisoli, Cristiano, Kwok, Wai-Kwong, and Wang, Yong-Lei

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Artificial spin ices are engineered arrays of dipolarly coupled nanobar magnets. They enable direct investigations of fascinating collective phenomena from their diverse microstates. However, experimental access to ground states in the geometrically frustrated systems has proven difficult, limiting studies and applications of novel properties and functionalities from the low energy states. Here, we introduce a convenient approach to control the competing diploar interactions between the neighboring nanomagnets, allowing us to tailor the vertex degeneracy of the ground states. We achieve this by tuning the length of selected nanobar magnets in the spin ice lattice. We demonstrate the effectiveness of our method by realizing multiple low energy microstates in a Kagome artificial spin ice, particularly the hardly accessible long range ordered ground state - the spin crystal state. Our strategy can be directly applied to other artificial spin systems to achieve exotic phases and explore new emergent collective behaviors., Comment: To appear in Physical Review Letters

Published
2022
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19. Writable spin wave nanochannels in an artificial-spin-ice-mediated ferromagnetic thin film

Author

Li, Jianhua, Xu, Wen-Bing, Yue, Wen-Cheng, Yuan, Zixiong, Gao, Tan, Wang, Ting-Ting, Xiao, Zhi-Li, Lyu, Yang-Yang, Li, Chong, Wang, Chenguang, Ma, Fusheng, Dong, Sining, Dong, Ying, Wang, Huabing, Wu, Peiheng, Kwok, Wai-Kwong, and Wang, Yong-Lei

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Magnonics, which employs spin-waves to transmit and process information, is a promising venue for low-power data processing. One of the major challenges is the local control of the spin-wave propagation path. Here, we introduce the concept of writable magnonics by taking advantage of the highly flexible reconfigurability and rewritability of artificial spin ice systems. Using micromagnetic simulations, we show that globally switchable spin-wave propagation and the locally writable spin-wave nanochannels can be realized in a ferromagnetic thin film underlying an artificial pinwheel spin ice. The rewritable magnonics enabled by reconfigurable spin wave nanochannels provides a unique setting to design programmable magnonic circuits and logic devices for ultra-low power applications., Comment: To appear in Applied Physics Letters

Published
2022
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23. Superconducting diode effect via conformal-mapped nanoholes

Author

Lyu, Yang-Yang, Jiang, Ji, Wang, Yong-Lei, Xiao, Zhi-Li, Dong, Sining, Chen, Qing-Hu, Milošević, Milorad V., Wang, Huabing, Divan, Ralu, Pearson, John E., Wu, Peiheng, Peeters, Francois M., and Kwok, Wai-Kwong

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics
Abstract

A superconducting diode is an electronic device that conducts supercurrent and exhibits zero resistance primarily for one direction of applied current. Such a dissipationless diode is a desirable unit for constructing electronic circuits with ultralow power consumption. However, realizing a superconducting diode is fundamentally and technologically challenging, as it usually requires a material structure without a centre of inversion, which is scarce among superconducting materials. Here, we demonstrate a superconducting diode achieved in a conventional superconducting film patterned with a conformal array of nanoscale holes, which breaks the spatial inversion symmetry. We showcase the superconducting diode effect through switchable and reversible rectification signals, which can be three orders of magnitude larger than that from a flux-quantum diode. The introduction of conformal potential landscapes for creating a superconducting diode is thereby proven as a convenient, tunable, yet vastly advantageous tool for superconducting electronics. This could be readily applicable to any superconducting materials, including cuprates and iron-based superconductors that have higher transition temperatures and are desirable in device applications., Comment: 25 pages, 4 figures

Published
2021
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24. Tailoring magnetization reversal of a single-domain bar nanomagnet via its end geometry

Author

Li, Jianhua, Dong, Sining, Yue, Wen-Cheng, Yuan, Zixiong, Xiao, Zhi-Li, Lyu, Yang-Yang, Wang, Ting-Ting, Li, Chong, Wang, Chenguang, Xu, Wen-Bing, Dong, Ying, Wang, Huabing, Wu, Peiheng, Kwok, Wai-Kwong, and Wang, Yong-Lei

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Nanoscale single-domain bar magnets are building blocks for a variety of fundamental and applied mesoscopic magnetic systems, such as artificial spin ices, magnetic shape-morphing microbots as well as magnetic majority logic gates. The magnetization reversal switching field of the bar nanomagnets is a crucial parameter that determines the physical properties and functionalities of their constituted artificial systems. Previous methods on tuning the magnetization reversal switching field of a bar nanomagnet usually rely on modifying its aspect ratio, such as its length, width and/or thickness. Here, we show that the switching field of a bar nanomagnet saturates when extending its length beyond a certain value, preventing further tailoring of the magnetization reversal via aspect ratios. We showcase highly tunable switching field of a bar nanomagent by tailoring its end geometry without altering its size. This provides an easy method to control the magnetization reversal of a single-domain bar nanomagnet. It would enable new research and/or applications, such as designing artificial spin ices with additional tuning parameters, engineering magnetic microbots with more flexibility as well as developing magnetic quantum-dot cellular automata systems for low power computing., Comment: 24 pages, 4 figures

Published
2021
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26. Reconfigurable pinwheel artificial-spin-ice and superconductor hybrid device

Author

Lyu, Yang-Yang, Ma, Xiaoyu, Xu, Jing, Wang, Yong-Lei, Xiao, Zhi-Li, Dong, Sining, Janko, Boldizsar, Wang, Huabing, Divan, Ralu, Pearson, John E., Wu, Peiheng, and Kwok, Wai-Kwong

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics
Abstract

The ability to control the potential landscape in a medium of interacting particles could lead to intriguing collective behavior and innovative functionalities. Here, we utilize spatially reconfigurable magnetic potentials of a pinwheel artificial spin ice structure to tailor the motion of superconducting vortices. The reconstituted chain structures of the magnetic charges in the artificial pinwheel spin ice and the strong interaction between magnetic charges and superconducting vortices allow significant modification of the transport properties of the underlying superconducting thin film, resulting in a reprogrammable resistance state that enables a reversible and switchable vortex Hall effect. Our results highlight an effective and simple method of using artificial spin ice as an in-situ reconfigurable nanoscale energy landscape to design reprogrammable superconducting electronics, which could also be applied to the in-situ control of properties and functionalities in other magnetic particle systems, such as magnetic skyrmions., Comment: To appear in Nano Letters

Published
2020
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30. Forex Trading Game in an Online Classroom with Heterogeneous Student Background

Author

Wang, Huabing

Abstract

This article presents a teaching exercise using real-time trading platform in an online international finance course with both finance and non-finance majors. The authors discuss their approach to accommodate to the on-line environment with the emphasis on preparation and flexibility, and present a statistical comparison of performance between online and on-campus students, which does not indicate significant differences.

Published
2018

40. Picosecond mode switching and Higgs amplitude mode in superconductor-metal hybrid terahertz metasurface

Author

Duan Siyu, Jiang Yushun, Wu Jingbo, Ji Lu, He Ming, Qiu Hongsong, Fan Kebin, Zhang Caihong, Zhu Guanghao, Jia Xiaoqing, Wang Huabing, Jin Biaobing, Chen Jian, and Wu Peiheng

Subjects
higgs amplitude mode, metasurface, superconducting film, terahertz, ultrafast modulation, Physics, QC1-999
Abstract

The ultrafast modulation of terahertz (THz) waves is essential for numerous applications, such as high-rate wireless communication, nonreciprocal transmission, and linear frequency conversion. However, high-speed THz devices are rare due to the lack of materials that rapidly respond to external stimuli. Here, we demonstrate a dynamic THz metasurface by introducing an ultrathin superconducting microbridge into metallic resonators to form a superconductor-metal hybrid structure. Exploiting the susceptibility of superconducting films to external optical and THz pumps, we realized resonance mode switching within a few picoseconds. The maximum on/off ratio achieved is 11 dB. The observed periodic oscillation of transmission spectra both in the time and frequency domain under intense THz pump pulse excitation reveals the excitation of Higgs amplitude mode, which is used to realize picosecond scale THz modulation. This study opens the door to ultrafast manipulation of THz waves using collective modes of condensates, and highlights an avenue for developing agile THz modulation devices.

Published
2022
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44. Integrated Metabolomics and Transcriptomics Analyses Reveal Metabolic Changes in Primary Angiitis of the Central Nervous System.

Author

Lu, Ping, Cui, Lingyun, Zhang, Lulin, Wang, Huabing, Yin, Linlin, Tian, Decai, and Zhang, Xinghu

Abstract

Purpose: Metabolic characterization of primary angiitis of the central nervous system (PACNS) is crucial for understanding the disease pathogenesis and progression mechanisms, but it has not been reported in patients. This study aimed to explore changes in the plasma metabolome during the active and remission phases of PACNS and identify potential biomarkers. Methods: We collected plasma samples from 35 patients with PACNS during the active and remission phases and 22 samples from patients with non-inflammatory disease as controls. Liquid and gas chromatography-mass spectrometry were used to analyze 63 plasma samples from 57 patients metabolically. Meanwhile, we cross-validated the metabolomics results with brain tissue transcriptomic data from comprehensive gene expression databases, enhancing the reliability of our conclusions. Results: A total of 3,233 metabolites were identified. Enrichment analysis showed significant changes in lactate/amino acid/glycerol–pyruvic–tricarboxylic acid, glycerophospholipid/sphingolipid-membrane metabolism, lysine/tryptophan-essential amino acid metabolism, and uracil metabolism pathways during the active phase of PACNS. These findings were confirmed in both the remission phase of PACNS patients and the transcriptomic samples. Meanwhile, metabolic abnormalities in patients with PACNS were observed with benzoxazole, sesquiterpenoid, and octyl-phenolic products, and enrichment of environmental pollutants and their estrogen-like effects. Twelve metabolites, including D-Ribose, 13s-HPODE, and C16 Sphinganine, showed potential diagnostic and therapeutic evaluation value. Conclusion: Our study identified potential biomarkers and metabolic characteristics of PACNS using integrated metabolomics and transcriptomics approaches. These findings highlight the importance of understanding PACNS from a metabolic perspective and guide future diagnostic and therapeutic strategies. [ABSTRACT FROM AUTHOR]

Published
2025
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45. Ultra-broadband near-field Josephson microwave microscopy.

Author

Zhang, Ping, Lyu, Yang-Yang, Lv, Jingjing, Wei, Zihan, Chen, Shixian, Wang, Chenguang, Du, Hongmei, Li, Dingding, Wang, Zixi, Hou, Shoucheng, Su, Runfeng, Sun, Hancong, Du, Yuan, Du, Li, Gao, Liming, Wang, Yong-Lei, Wang, Huabing, and Wu, Peiheng

Subjects
JOSEPHSON junctions, MICROWAVE circuits, MICROWAVE imaging, MICROWAVE photonics, SPECTROSCOPIC imaging, MICROWAVE devices
Abstract

Advanced microwave technologies constitute the foundation of a wide range of modern sciences, including microwave integrated circuits, quantum computing, microwave photonics, spintronics, etc. To facilitate the design of chip-based microwave devices, there is an increasing demand for state-of-the-art microscopic techniques that are capable of characterizing near-field microwave distribution and performance. In this work, we integrate Josephson junctions onto a nanosized quartz tip, forming a highly sensitive microwave mixer on-tip. This allows us to conduct spectroscopic imaging of near-field microwave distributions with high spatial resolution. By leveraging its microwave-sensitive characteristics, our Josephson microscopy achieves a broad detecting bandwidth of ≤200 GHz, as well as remarkable frequency and intensity resolutions. Near-field characterizations of microwave circuits are also conducted to demonstrate the capabilities of Josephson microscopy. Our work emphasizes the benefits of utilizing Josephson microscopy as a real-time, non-destructive technique to advance integrated microwave devices. [ABSTRACT FROM AUTHOR]

Published
2025
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46. Bank health, lines of credit, and corporate investment: evidence from the Great Recession.

Author

Zhang, Wei, Macy, Anne, and Wang, Huabing

Subjects
FINANCIAL crises, LINES of credit, TREATMENT effect heterogeneity, CORPORATE investments, BANK liquidity
Abstract

We study whether and how bank health affects corporate investment during the Great Recession. Using loan-level data, we find that firms obtain fewer lines of credit from less healthy lenders during the crisis among participants in the firms' last precrisis credit line syndicate, supporting the transmission of bank liquidity shocks to firms. However, bank health has heterogeneous treatment effects on corporate liquidity and investment. Bank health has a strong positive impact on lines of credit growth and investment growth only for firms with precrisis lines of credit maturing in the crisis, and the effect is concentrated in smaller firms and firms with weaker banking relationships. Thus, the transmission is arbitrary and uneven based on the timing of lines of credit instead of firm quality. We conclude that lines of credit play a significant role in transmitting bank liquidity shocks to firms, especially important given recent events and how quickly contagion can occur. [ABSTRACT FROM AUTHOR]

Published
2025
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47. Superconducting (Li, Fe)OHFeSe film of high quality and high critical parameters

Author

Huang, Yulong, Feng, Zhongpei, Ni, Shunli, Li, Jun, Hu, Wei, Liu, Shaobo, Mao, Yiyuan, Zhou, Huaxue, Zhou, Fang, Jin, Kui, Wang, Huabing, Yuan, Jie, Dong, Xiaoli, and Zhao, Zhongxian

Subjects
Condensed Matter - Superconductivity
Abstract

The superconducting film of (Li1-xFex)OHFeSe is reported for the first time. The thin film exhibits a small in-plane crystal mosaic of 0.22 deg, in terms of the FWHM (full-width-at-half-maximum) of x-ray rocking curve, and an excellent out-of-plane orientation by x-ray phi-scan. Its bulk superconducting transition temperature (Tc) of 42.4 K is characterized by both zero electrical resistance and diamagnetization measurements. The upper critical field (Hc2) is estimated to be 79.5 T and 443 T, respectively, for the magnetic field perpendicular and parallel to the ab plane. Moreover, a large critical current density (Jc) of a value over 0.5 MA/cm2 is achieved at ~20 K. Such a (Li1-xFex)OHFeSe film is therefore not only important to the fundamental research for understanding the high-Tc mechanism, but also promising in the field of high-Tc superconductivity application, especially in high-performance electronic devices and large scientific facilities such as superconducting accelerator., Comment: 9 pages, 4 figures

Published
2017
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48. Promoting superconductivity in FeSe films via fine manipulation of crystal lattice

Author

Feng, Zhongpei, Yuan, Jie, He, Ge, Lin, Zefeng, Li, Dong, Jiang, Xingyu, Huang, Yulong, Ni, Shunli, Li, Jun, Zhu, Beiyi, Dong, Xiaoli, Zhou, Fang, Wang, Huabing, Zhao, Zhongxian, and Jin, Kui

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Materials Science
Abstract

Stabilized FeSe thin films in ambient pressure with tunable superconductivity would be a promising candidate for superconducting electronic devices yet its superconducting transition temperature (Tc) is below 10 K in bulk materials. By carefully controlling the depositions on twelve kinds of substrates using pulsed laser deposition technique, high quality single crystalline FeSe samples were fabricated with full width of half maximum 0.515? in the rocking curve and clear four-fold symmetry in phi-scan from x-ray diractions. The films have a maximum Tc 15 K on the CaF2 substrate and do not show obvious decay in the air for more than half a year. Slightly tuning the stoichiometry of the FeSe targets, the Tc becomes adjustable from 15 to < 2 K with quite narrow transition widths less than 2 K, and shows a positive relation with the out-of-plane (c-axis) lattice parameter of the films. However, there is no clear relation between the Tc and the surface atomic distance of the substrates. By reducing the thickness of the films, the Tc decreases and fades away in samples of less than 10 nm, suggesting that the strain effect is not responsible for the enhancement of Tc in our experiments., Comment: 5 pages, 4 figures

Published
2017

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