Your search keyword '"Liu, Wen-bo"' showing total 774 results

1. Continuous-variable quantum digital signatures that can withstand coherent attacks

Author

Zhang, Yi-Fan, Liu, Wen-Bo, Li, Bing-Hong, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics

Abstract

Quantum digital signatures (QDSs), which utilize correlated bit strings among sender and recipients, guarantee the authenticity, integrity, and nonrepudiation of classical messages based on quantum laws. Continuous-variable (CV) quantum protocol with heterodyne and homodyne measurement has obvious advantages of low-cost implementation and easy wavelength division multiplexing. However, security analyses in previous researches are limited to the proof against collective attacks in finite-size scenarios. Moreover, existing multibit CV QDS schemes have primarily focused on adapting single-bit protocols for simplicity of security proof, often sacrificing signature efficiency. Here, we introduce a CV QDS protocol designed to withstand general coherent attacks through the use of a cutting-edge fidelity test function, while achieving high signature efficiency by employing a refined one-time universal hashing signing technique. Our protocol is proved to be robust against finite-size effects and excess noise in quantum channels. In simulation, results demonstrate a significant reduction of eight orders of magnitude in signature length for a megabit message signing task compared with existing CV QDS protocols and this advantage expands as the message size grows. Our work offers a solution with enhanced security and efficiency, paving the way for large-scale deployment of CV QDSs in future quantum networks., Comment: 19 pages, 8 figures

Published

2024

2. Discrete-Modulated Continuous-Variable Quantum Key Distribution in Satellite-to-Ground Communication

Author

Li, Shi-Gen, Li, Chen-Long, Liu, Wen-Bo, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics

Abstract

Satellite-to-ground quantum communication constitutes the cornerstone of the global quantum network, heralding the advent of the future of quantum information. Continuous-variable quantum key distribution is a strong candidate for space-ground quantum communication due to its simplicity, stability, and ease of implementation, especially for the robustness of space background light noise. Recently, the discrete-modulated continuous-variable protocol has garnered increased attention, owing to its lower implementation requirements, acceptable security key rate, and pronounced compatibility with extant infrastructures. Here, we derive key rates for discrete-modulated continuous-variable quantum key distribution protocols in free-space channel environments across various conditions through numerical simulation, revealing the viability of its application in satellite-to-ground communication., Comment: 12 pages, 6 figures

Published

2024

3. Experimental quantum secret sharing based on phase encoding of coherent states

Author

Shen, Ao, Cao, Xiao-Yu, Wang, Yang, Fu, Yao, Gu, Jie, Liu, Wen-Bo, Weng, Chen-Xun, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics, Computer Science - Cryptography and Security

Abstract

Quantum secret sharing (QSS) is one of the basic communication primitives in future quantum networks which addresses part of the basic cryptographic tasks of multiparty communication and computation. Nevertheless, it is a challenge to provide a practical QSS protocol with security against general attacks. A QSS protocol that balances security and practicality is still lacking. Here, we propose a QSS protocol with simple phase encoding of coherent states among three parties. Removing the requirement of impractical entangled resources and the need for phase randomization, our protocol can be implemented with accessible technology. We provide the finite-key analysis against coherent attacks and implement a proof-of-principle experiment to demonstrate our scheme's feasibility. Our scheme achieves a key rate of 85.3 bps under a 35 dB channel loss. Combined with security against general attacks and accessible technology, our protocol is a promising candidate for practical multiparty quantum communication networks., Comment: 10 pages, 5 figures, 3 tables, accepted by Sci. China-Phys. Mech. Astron

Published

2023

4. Phase-Matching Quantum Key Distribution without Intensity Modulation

Author

Shao, Shan-Feng, Cao, Xiao-Yu, Xie, Yuan-Mei, Gu, Jie, Liu, Wen-Bo, Fu, Yao, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics, Computer Science - Cryptography and Security

Abstract

Quantum key distribution provides a promising solution for sharing secure keys between two distant parties with unconditional security. Nevertheless, quantum key distribution is still severely threatened by the imperfections of devices. In particular, the classical pulse correlation threatens security when sending decoy states. To address this problem and simplify experimental requirements, we propose a phase-matching quantum key distribution protocol without intensity modulation. Instead of using decoy states, we propose a novel method to estimate the theoretical upper bound on the phase error rate contributed by even-photon-number components. Simulation results show that the transmission distance of our protocol could reach 305 km in telecommunication fiber. Furthermore, we perform a proof-of-principle experiment to demonstrate the feasibility of our protocol, and the key rate reaches 22.5 bps under a 45 dB channel loss. Addressing the security loophole of pulse intensity correlation and replacing continuous random phase with 6 or 8 slices random phase, our protocol provides a promising solution for constructing quantum networks., Comment: Comments are welcome! 12 pages, 6 figures

Published

2023

5. All-Photonic Quantum Repeater for Multipartite Entanglement Generation

Author

Li, Chen-Long, Fu, Yao, Liu, Wen-Bo, Xie, Yuan-Mei, Li, Bing-Hong, Zhou, Min-Gang, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics

Abstract

Quantum network applications like distributed quantum computing and quantum secret sharing present a promising future network equipped with quantum resources. Entanglement generation and distribution over long distances is critical and unavoidable to utilize quantum technology in a fully-connected network. The distribution of bipartite entanglement over long distances has seen some progresses, while the distribution of multipartite entanglement over long distances remains unsolved. Here we report a two-dimensional quantum repeater protocol for the generation of multipartite entanglement over long distances with all-photonic framework to fill this gap. The yield of the proposed protocol shows long transmission distance under various numbers of network users. With the improved efficiency and flexibility of extending the number of users, we anticipate that our protocol can work as a significant building block for quantum networks in the future.

Published

2022

6. Breaking universal limitations on quantum conference key agreement without quantum memory

Author

Li, Chen-Long, Fu, Yao, Liu, Wen-Bo, Xie, Yuan-Mei, Li, Bing-Hong, Zhou, Min-Gang, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics, Computer Science - Cryptography and Security

Abstract

Quantum conference key agreement is an important cryptographic primitive for future quantum network. Realizing this primitive requires high-brightness and robust multiphoton entanglement sources, which is challenging in experiment and unpractical in application because of limited transmission distance caused by channel loss. Here we report a measurement-device-independent quantum conference key agreement protocol with enhanced transmission efficiency over lossy channel. With spatial multiplexing nature and adaptive operation, our protocol can break key rate bounds on quantum communication over quantum network without quantum memory. Compared with previous work, our protocol shows superiority in key rate and transmission distance within the state-of-the-art technology. Furthermore, we analyse the security of our protocol in the composable framework and evaluate its performance in the finite-size regime to show practicality. Based on our results, we anticipate that our protocol will play an indispensable role in constructing multipartite quantum network., Comment: 9 pages, 4 figures, 1 table

Published

2022

7. Breaking Rate-Distance Limitation of Measurement-Device-Independent Quantum Secret Sharing

Author

Li, Chen-Long, Fu, Yao, Liu, Wen-Bo, Xie, Yuan-Mei, Li, Bing-Hong, Zhou, Min-Gang, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics, Computer Science - Cryptography and Security

Abstract

Currently most progresses on quantum secret sharing suffer from rate-distance bound, and thus the key rates are limited. In addition to the limited key rate, the technical difficulty and the corresponding cost together prevent large-scale deployment. Furthermore, the performance of most existing protocols is analyzed in the asymptotic regime without considering participant attacks. Here we report a measurement-device-independent quantum secret sharing protocol with improved key rate and transmission distance. Based on spatial multiplexing, our protocol shows it can break rate-distance bounds over network under at least ten communication parties. Compared with other protocols, our work improves the secret key rate by more than two orders of magnitude and has a longer transmission distance. We analyze the security of our protocol in the composable framework considering participant attacks and evaluate its performance in the finite-size regime. In addition, we investigate applying our protocol to digital signatures where the signature rate is improved more than $10^7$ times compared with existing protocols. We anticipate that our quantum secret sharing protocol will provide a solid future for multiparty applications on the quantum network., Comment: 14 pages, 6 figs, arXiv admin note: text overlap with arXiv:2212.05226

Published

2022

8. Structure engineering of cathode host materials for Li–S batteries

Author

Long, Jia-Jun, Yu, Hua, and Liu, Wen-Bo

Published

2024

9. General framework of quantum complementarity from a measurement-based perspective

Author

Huang, Shan, Liu, Wen-Bo, Zhao, Yundu, Yin, Hua-Lei, Chen, Zeng-Bing, and Wu, Shengjun

Subjects

Quantum Physics

Abstract

One of the most remarkable features of quantum physics is that attributes of quantum objects, such as the wave-like and particle-like behaviors of single photons, can be complementary in the sense that they are equally real but cannot be observed simultaneously. Quantum measurements, serving as windows providing views into the abstract edifice of quantum theory, are basic tools for manifesting the intrinsic behaviors of quantum objects. However, quantitative formulation of complementarity that highlights its manifestations in sophisticated measurements remains elusive. Here we develop a general framework for demonstrating quantum complementarity in the form of information exclusion relations (IERs), which incorporates the wave-particle duality relations as particular examples. Moreover, we explore the applications of our theory in entanglement witnessing and elucidate that our IERs lead to an extended form of entropic uncertainty relations, providing intriguing insights into the connection between quantum complementarity and the preparation uncertainty., Comment: 13 pages (including 7 pages in the main text), 6 figures

Published

2022

10. Beating the fault-tolerance bound and security loopholes for Byzantine agreement with a quantum solution

Author

Weng, Chen-Xun, Gao, Rui-Qi, Bao, Yu, Li, Bing-Hong, Liu, Wen-Bo, Xie, Yuan-Mei, Lu, Yu-Shuo, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics, Computer Science - Cryptography and Security

Abstract

Byzantine agreement, the underlying core of blockchain, aims to make every node in a decentralized network reach consensus. Classical Byzantine agreements unavoidably face two major problems. One is $1/3$ fault-tolerance bound, which means that the system to tolerate $f$ malicious players requires at least $3f+1$ players. The other is the security loopholes from its classical cryptography methods. Here, we propose a Byzantine agreement framework with unconditional security to break this bound with nearly $1/2$ fault tolerance due to multiparty correlation provided by quantum digital signatures. \textcolor{black}{It is intriguing that quantum entanglement is not necessary to break the $1/3$ fault-tolerance bound, and we show that weaker correlation, such as asymmetric relationship of quantum digital signature, can also work.} Our work strictly obeys two Byzantine conditions and can be extended to any number of players without requirements for multiparticle entanglement. We experimentally demonstrate three-party and five-party consensus for a digital ledger. Our work indicates the quantum advantage in terms of consensus problems and suggests an important avenue for quantum blockchain and quantum consensus networks., Comment: 21 pages, 7 figures. All comments are welcome!

Published

2022

11. A protein structure-dependent fluorescent probe for hemoglobin monitoring and controllable imaging in living cells

Author

Yan, Xian-Ting, Chang, Kai-Li, Huang, Zi-Bei, Xu, Yun-Tiao, Li, Zi-Pan, Liu, Wen-Bo, and Wang, Qing

Published

2024

12. Source-independent quantum random number generator against tailored detector blinding attacks

Author

Liu, Wen-Bo, Lu, Yu-Shuo, Fu, Yao, Huang, Si-Cheng, Yin, Ze-Jie, Jiang, Kun, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics, Computer Science - Cryptography and Security

Abstract

Randomness, mainly in the form of random numbers, is the fundamental prerequisite for the security of many cryptographic tasks. Quantum randomness can be extracted even if adversaries are fully aware of the protocol and even control the randomness source. However, an adversary can further manipulate the randomness via tailored detector blinding attacks, which are hacking attacks suffered by protocols with trusted detectors. Here, by treating no-click events as valid events, we propose a quantum random number generation protocol that can simultaneously address source vulnerability and ferocious tailored detector blinding attacks. The method can be extended to high-dimensional random number generation. We experimentally demonstrate the ability of our protocol to generate random numbers for two-dimensional measurement with a generation speed of 0.1 bit per pulse., Comment: 14 pages, 6 figures, 6 tables, comments are welcome

Published

2022

13. Chiral discrimination of small substituents in biaryl atropisomer construction: enantioselective synthesis of axially chiral 1-azafluorene via Ni-catalyzed [2+2+2] cycloaddition

Author

Peng, Jin-Huang, Zheng, Yu-Qing, Bai, Li-Gang, and Liu, Wen-Bo

Published

2023

14. Automated machine learning for secure key rate in discrete-modulated continuous-variable quantum key distribution

Author

Liu, Zhi-Ping, Zhou, Min-Gang, Liu, Wen-Bo, Li, Chen-Long, Gu, Jie, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics, Computer Science - Cryptography and Security, Computer Science - Machine Learning

Abstract

Continuous-variable quantum key distribution (CV QKD) with discrete modulation has attracted increasing attention due to its experimental simplicity, lower-cost implementation and compatibility with classical optical communication. Correspondingly, some novel numerical methods have been proposed to analyze the security of these protocols against collective attacks, which promotes key rates over one hundred kilometers of fiber distance. However, numerical methods are limited by their calculation time and resource consumption, for which they cannot play more roles on mobile platforms in quantum networks. To improve this issue, a neural network model predicting key rates in nearly real time has been proposed previously. Here, we go further and show a neural network model combined with Bayesian optimization. This model automatically designs the best architecture of neural network computing key rates in real time. We demonstrate our model with two variants of CV QKD protocols with quaternary modulation. The results show high reliability with secure probability as high as $99.15\%-99.59\%$, considerable tightness and high efficiency with speedup of approximately $10^7$ in both cases. This inspiring model enables the real-time computation of unstructured quantum key distribution protocols' key rate more automatically and efficiently, which has met the growing needs of implementing QKD protocols on moving platforms., Comment: 9 pages, 5 figures

Published

2022

15. Fatigue experiment and assessment of Q420qFNH weathering steel in the unequal-thickness butt-welded joint

Author

Cui, Chuang, Liu, Wen-bo, Tian, Yu-Xiang, and Zhang, Qing-hua

Published

2024

16. Role of cation nature in crown ether appended 25-Oxasmaragdyrins with second-order NLO responses: As potential and selective metal ions detector

Author

Liu, Wen-bo, Huang, Xiao, Gao, Feng-wei, Liu, Xing-man, and Xu, Hong-liang

Published

2024

17. Neural network-based prediction of the secret-key rate of quantum key distribution

Author

Zhou, Min-Gang, Liu, Zhi-Ping, Liu, Wen-Bo, Li, Chen-Long, Bai, Jun-Lin, Xue, Yi-Ran, Fu, Yao, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics

Abstract

Numerical methods are widely used to calculate the secure key rate of many quantum key distribution protocols in practice, but they consume many computing resources and are too time-consuming. In this work, we take the homodyne detection discrete-modulated continuous-variable quantum key distribution (CV-QKD) as an example, and construct a neural network that can quickly predict the secure key rate based on the experimental parameters and experimental results. Compared to traditional numerical methods, the speed of the neural network is improved by several orders of magnitude. Importantly, the predicted key rates are not only highly accurate but also highly likely to be secure. This allows the secure key rate of discrete-modulated CV-QKD to be extracted in real time on a low-power platform. Furthermore, our method is versatile and can be extended to quickly calculate the complex secure key rates of various other unstructured quantum key distribution protocols., Comment: 12 pages, 5 figures, 2 tables

Published

2021

18. Enhanced performance of cesium copper halide nanocrystal light-emitting diodes via post-treatment induced phase regulation

Author

Liu, Wen-bo, Du, Xue-rong, Wang, Cheng-cheng, Zhuo, Chun-xue, Chang, Jin, Wang, Na-na, and Li, Ren-zhi

Published

2023

19. Research Progress of spiking neural network in image classification: a review

Author

Niu, Li-Ye, Wei, Ying, Liu, Wen-Bo, Long, Jun-Yu, and Xue, Tian-hao

Published

2023

20. Simple security proof of coherent-one-way quantum key distribution

Author

Gao, Rui-Qi, Xie, Yuan-Mei, Gu, Jie, Liu, Wen-Bo, Weng, Chen-Xun, Li, Bing-Hong, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics

Abstract

Coherent-one-way quantum key distribution (COW-QKD), which requires a simple experimental setup and has the ability to withstand photon-number-splitting attacks, has been not only experimentally implemented but also commercially applied. However, recent studies have shown that the current COW-QKD system is insecure and can only distribute secret keys safely within 20 km of the optical fiber length. In this study, we propose a practical implementation of COW-QKD by adding a two-pulse vacuum state as a new decoy sequence. This proposal maintains the original experimental setup as well as the simplicity of its implementation. Utilizing detailed observations on the monitoring line to provide an analytical upper bound on the phase error rate, we provide a high-performance COW-QKD asymptotically secure against coherent attacks. This ensures the availability of COW-QKD within 100 km and establishes theoretical foundations for further applications., Comment: 8 pages, 5 figures, 1 table, Typos corrected

Published

2021

21. Homodyne Detection Quadrature Phase Shift Keying Continuous-Variable Quantum Key Distribution with High Excess Noise Tolerance

Author

Liu, Wen-Bo, Li, Chen-Long, Xie, Yuan-Mei, Weng, Chen-Xun, Gu, Jie, Cao, Xiao-Yu, Lu, Yu-Shuo, Li, Bing-Hong, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics

Abstract

Discrete-modulated continuous-variable quantum key distribution with homodyne detection is widely recognized for its ease of implementation, efficiency with respect to error correction, and its compatibility with modern optical communication devices. However, recent studies report that the application of homodyne detection obtains poor tolerance to excess noise and insufficient transmission distance, hence seriously restricting the large-scale deployment of quantum secure communication networks. In this paper, we propose a homodyne detection protocol using the quadrature phase shift keying technique. By limiting information leakage, our proposed protocol enhances excess noise tolerance to a high level. Furthermore, we demonstrate that homodyne detection performs better than heterodyne detection in quaternary-modulated continuous-variable quantum key distribution under the untrusted detector noise scenario. The security is analyzed using the tight numerical method against collective attacks in the asymptotic regime. Our results imply that the current protocol is able to distribute keys in nearly intercity area and thus paves the way for constructing low-cost quantum secure communication networks., Comment: 14 pages, 10 figures. Accepted by PRX Quantum

Published

2021

22. Secure Quantum Secret Sharing without Signal Disturbance Monitoring

Author

Yin, Hua-Lei, Gu, Jie, Xie, Yuan-Mei, Liu, Wen-Bo, Fu, Yao, and Chen, Zeng-Bing

Subjects

Quantum Physics

Abstract

Quantum secret sharing (QSS) is an essential primitive for the future quantum internet, which promises secure multiparty communication. However, developing a large-scale QSS network is a huge challenge due to the channel loss and the requirement of multiphoton interference or high-fidelity multipartite entanglement distribution. Here, we propose a three-user QSS protocol without monitoring signal disturbance, which is capable of ensuring the unconditional security. The final key rate of our protocol can be demonstrated to break the Pirandola-Laurenza-Ottaviani-Banchi bound of quantum channel and its simulated transmission distance can approach over 600 km using current techniques. Our results pave the way to realizing high-rate and large-scale QSS networks., Comment: 8 pages, 5 figures

Published

2021

23. Overcoming the rate-distance limit of device-independent quantum key distribution

Author

Xie, Yuan-Mei, Li, Bing-Hong, Lu, Yu-Shuo, Cao, Xiao-Yu, Liu, Wen-Bo, Yin, Hua-Lei, and Chen, Zeng-Bing

Subjects

Quantum Physics

Abstract

Device-independent quantum key distribution (DIQKD) exploits the violation of a Bell inequality to extract secure key even if the users' devices are untrusted. Currently, all DIQKD protocols suffer from the secret key capacity bound, i.e., the secret key rate scales linearly with the transmittance of two users. Here we propose a heralded DIQKD scheme based on entangled coherent states to improve entangling rates whereby long-distance entanglement is created by single-photon-type interference. The secret key rate of our scheme can significantly outperform the traditional two-photon-type Bell-state measurement scheme and, importantly, surpass the above capacity bound. Our protocol therefore is an important step towards a realization of DIQKD and can be a promising candidate scheme for entanglement swapping in future quantum internet., Comment: 5 pages, 3 figures

Published

2021

24. Spatiotemporal Backpropagation based on Channel Reward for Training High-Precision Spiking Neural Network

Author

Niu, Li-Ye, Wei, Ying, Liu, Yue, Long, Jun-Yu, and Liu, Wen-Bo

Published

2023

25. External electric field driven conformation of the wing-shaped nanographene to close: enhancing and tuning nonlinear optical properties

Author

Gan, Ping-yao, Huang, Xiao, Liu, Wen-bo, Bai, Xue, Zhang, Xing-jian, Gao, Feng-wei, Xu, Hong-liang, and Su, Zhong-min

Published

2023

26. T817MA Regulates Mitochondrial Dynamics via Sirt1 and Arc Following Subarachnoid Hemorrhage

Author

Chen, Wei-Wei, Sun, Fu-Qiang, Wang, Bo, Tian, Xiao-Xiao, Zhang, Rong-Ping, and Liu, Wen-Bo

Published

2023

27. A potential nonlinear optical material for crown-porphyrin complexes: Alkali metal doping and transition metal introducing

Author

Liu, Wen-bo, Gan, Ping-yao, Huang, Xiao, Gao, Feng-wei, and Xu, Hong-liang

Published

2023

28. A heterozygous ZP2 mutation causes zona pellucida defects and female infertility in mouse and human

Author

Liu, Sai-Li, Zuo, Hai-Yang, Zhao, Bing-Wang, Guo, Jia-Ni, Liu, Wen-Bo, Lei, Wen-Long, Li, Yuan-Yuan, Ouyang, Ying-Chun, Hou, Yi, Han, Zhi-Ming, Wang, Wei-Zhou, Sun, Qing-Yuan, and Wang, Zhen-Bo

Published

2023

29. Discovery of novel N-benzylarylamide-dithiocarbamate based derivatives as dual inhibitors of tubulin polymerization and LSD1 that inhibit gastric cancers

Author

Yuan, Xin-Ying, Song, Chun-Hong, Liu, Xiu-Juan, Wang, Xiao, Jia, Mei-Qi, Wang, Wang, Liu, Wen-Bo, Fu, Xiang-Jing, Jin, Cheng-Yun, Song, Jian, and Zhang, Sai-Yang

Published

2023

30. Hot deformation behavior and microstructure features of FeCrAl–ODS alloy

Author

Long, Di-jun, Qiu, Shao-yu, Liu, Wen-bo, Sun, Yong-duo, Luo, Wei, Liu, Hui-qun, and Zhang, Rui-qian

Published

2022

31. The efficacy of Da Chaihu decoction combined with metformin tablets for type 2 diabetes mellitus: A systematic review and meta-analysis

Author

Wang, Jia-bin, Wang, Yan-xia, Li, Fen, Li, Yan-fei, Li, Xing-li, Huang, Pei-yao, Wang, Chen, Wang, Meng, Qiu, Jie, Yang, Ke-hu, Qiu, Wen-wen, Liu, Lu, Mao, Bao-hong, Li, Hong-pu, Liu, Xu-dong, Li, Fu-yun, Cui, Xu-dong, wang, peng-ju, and Liu, Wen-bo

Published

2022

32. [2+2+2] Cycloaddition of nitriles to enantioenriched and highly substituted pyridines

Author

Cai, Jinhui, Cen, Kaili, Shen, Wangzhen, Bai, Li-Gang, and Liu, Wen-Bo

Published

2022

33. Discovery of novel coumarin-indole derivatives as tubulin polymerization inhibitors with potent anti-gastric cancer activities

Author

Song, Jian, Guan, Yong-Feng, Liu, Wen-Bo, Song, Chun-Hong, Tian, Xin-Yi, Zhu, Ting, Fu, Xiang-Jing, Qi, Ying-Qiu, and Zhang, Sai-Yang

Published

2022

34. A novel aromatic amide derivative SY-65 co-targeted tubulin and histone deacetylase 1 with potent anticancer activity in vitro and in vivo

Author

Li, Yin-Ru, Liu, Fang-Fang, Liu, Wen-Bo, Zhang, Yi-Fan, Tian, Xin-Yi, Fu, Xiang-Jing, Xu, Yan, Song, Jian, and Zhang, Sai-Yang

Published

2022

35. Research and Application Progress of Silica Sols in the Field of Wood.

Author

WANG Chang-yu, WANG Hong-xing, LIU Xue-ying, LIU Wen-bo, LIU Ming-li, and LI Chun-feng

Subjects

WOOD chemistry, COLLOIDS, FIREPROOFING, SILICA, ION exchange (Chemistry), NANOSTRUCTURED materials

Abstract

Silica sol is a high-performance nanomaterial widely used, and its synthesis methods mainly include ion exchange method, electrolytic electrodialysis method, dispersion method, etc. However, the performance of silica sol synthesized by different methods varies. In order to improve its drawbacks, it is often necessary to modify the silica sol, and common modification methods are mainly divided into physical modification and chemical modification. In this article, the synthesis methods, modification methods, and modified properties of silica sol were summarized, and its application in the field of wood was examined. The focus is on the relevant research on improving the mechanical properties and flame retardancy of wood. Finally, the development of silica sol in the field of wood was discussed. [ABSTRACT FROM AUTHOR]

Published

2024

36. Neonatal Exposure to Propofol Interferes with the Proliferation and Differentiation of Hippocampal Neural Stem Cells and the Neurocognitive Function of Rats in Adulthood via the Akt/p27 Signaling Pathway

Author

MIAO, Hui Hui, LIU, Wen Bo, JIAO, Xin Hao, SHAO, Ke Jie, YUAN, Ying Xuan, SHA, Sha, ZHANG, Qi Qi, YAN, Jing, SUN, Yin Ying, ZHOU, Cheng Hua, and WU, Yu Qing

Published

2022

37. Discovery of novel 1,2,4-triazine-chalcone hybrids as anti-gastric cancer agents via an axis of ROS-ERK-DR5 in vitro and in vivo

Author

Liu, Chong, Song, Jian, Cui, Xin-Xin, Liu, Wen-Bo, Li, Yin-Ru, Yu, Guang-Xi, Tian, Xin-Yi, Wang, Ya-Feng, Liu, Yang, and Zhang, Sai-Yang

Published

2022

38. High-Accuracy Spiking Neural Network for Objective Recognition Based on Proportional Attenuating Neuron

Author

Niu, Li-Ye, Wei, Ying, Long, Jun-Yu, and Liu, Wen-Bo

Published

2022

39. Hybrid MPI+OpenMP Parallel Method on Polyhedral Grid Generation in OpenFoam

Author

LIU Jiang, LIU Wen-bo, ZHANG Ju

Subjects

computational fluid dynamics, openfoam, polyhedral grid generation, mpi+openmp hybrid parallelization, parallel efficiency, Computer software, QA76.75-76.765, Technology (General), T1-995

Abstract

Grid generation is an important step of computational fluid dynamics.In the process of large-scale numerical simulation,the time consumption of grid generation increases with the number of grids which often increases with the simulation accuracy.Based on the grid generation algorithm in an open-source software called OpenFoam,this paper proposes a hybrid parallel me-thod of OpenMP and MPI for polyhedral grid generation.By theoretical analysis,we show that when the hybrid parallel method is used to generate the same quality grids,increasing the number of threads and grid cells will reduce the time consumption of grid generation.Three numerical simulations using different solvers show that the grids generated by the hybrid parallel method and the original method have close qualifications,and the simulation results are almost indistinguishable from those of the original method.Furthermore,the time consumption of this method to generate the same quality and quantity grids can be reduced to less than a quarter of the time consumption without using OpenMP parallel method.

Published

2022

40. From Quaternary Carbon to Tertiary C(sp3)–Si and C(sp3)–Ge Bonds: Decyanative Coupling of Malononitriles with Chlorosilanes and Chlorogermanes Enabled by Ni/Ti Dual Catalysis

Author

Chen, Zi-Hao, primary, Zheng, Yu-Qing, additional, Huang, Hong-Gui, additional, Wang, Ke-Hao, additional, Gong, Jun-Lin, additional, and Liu, Wen-Bo, additional

Published

2024

41. Discovery of 1,2,4-triazine dithiocarbamate derivatives as NEDDylation agonists to inhibit gastric cancers

Author

Song, Jian, Liu, Yuan, Yuan, Xin-Ying, Liu, Wen-Bo, Li, Yin-Ru, Yu, Guang-Xi, Tian, Xin-Yi, Zhang, Yan-Bing, Fu, Xiang-Jing, and Zhang, Sai-Yang

Published

2021

42. A new A3B zinc(II)-porphyrin ligand and its ruthenium(II) complex: Synthesis, photophysical properties and photocatalytic applications

Author

Yu, Xiu-yue, Su, Hui, Zheng, Xin, Liu, Wen-bo, He, Yao, Fei, Na-na, Qiao, Ru, Ren, Yun-lai, and Niu, Cao-yuan

Published

2021

43. Recent progress of oridonin and its derivatives for cancer therapy and drug resistance

Author

Guan, Yong-Feng, Liu, Xiu-Juan, Pang, Xiao-Jing, Liu, Wen-Bo, Yu, Guang -Xi, Li, Yin -Ru, Zhang, Yan-Bing, Song, Jian, and Zhang, Sai-Yang

Published

2021

44. Recrystallization and texture evolution of cold-rolled FeCrAl thin-wall tube with large Laves phase during annealing: Effect of Nb content

Author

Liu, Zhe, Chen, Jing, Liu, Wen-bo, Liu, Hui-qun, Du, Pei-nan, and Zhang, Rui-qian

Published

2021

45. Ni-catalyzed enantioselective [2 + 2 + 2] cycloaddition of malononitriles with alkynes

Author

Cai, Jinhui, Bai, Li-Gang, Zhang, Yiliang, Wang, Zhen-Kai, Yao, Fei, Peng, Jin-Huang, Yan, Wei, Wang, Yan, Zheng, Chao, and Liu, Wen-Bo

Published

2021

46. A novel dimer-induced AIE material as a nano-sensor for colormetric and ratiometric sensing of Erythromycin and metal ions (Zn2+, Cd2+ and Cu2+) with different dissociation and re-aggregation processes and cellular imaging applications

Author

Li, Na-Na, Xue, Jing, Zhang, Xia, Shi, Ning-Ning, Liu, Wen-Bo, Wu, Rui-xue, Fan, Chuan-Bin, Xu, Cun-Gang, Bi, Shuang-Yu, and Fan, Yu-Hua

Published

2021

47. Pd/Cu Dual Metal-Catalyzed Regioselective [2 + 2 + 2] Cycloaddition of Malononitriles with Alkynes to Densely Substituted Pyridines.

Author

Wang, Xing-Zhen, Huang, Hong-Gui, and Liu, Wen-Bo

Published

2024

48. Discrete‐Modulated Continuous‐Variable Quantum Key Distribution in Satellite‐to‐Ground Communication.

Author

Li, Shi‐Gen, Li, Chen‐Long, Liu, Wen‐Bo, Yin, Hua‐Lei, and Chen, Zeng‐Bing

Subjects

HETERODYNE detection, QUANTUM communication, COMPUTER simulation, SIMPLICITY, NOISE

Abstract

Satellite‐to‐ground quantum communication constitutes the cornerstone of the global quantum network, heralding the advent of the future of quantum information. Continuous‐variable quantum key distribution is a strong candidate for the space‐ground quantum communication due to its simplicity, stability, and ease of implementation, especially for the robustness of space background light noise. Recently, the discrete‐modulated continuous‐variable protocol has garnered increased attention, owing to its lower implementation requirements, acceptable security key rate, and pronounced compatibility with extant infrastructures. Here, key rates are derived for discrete‐modulated continuous‐variable quantum key distribution protocols in free‐space channel environments across various conditions through numerical simulation, revealing the viability of its application in satellite‐to‐ground communication. [ABSTRACT FROM AUTHOR]

Published

2024

49. Efficient and selective adsorption of dye in aqueous environment employing a functional Zn(Ⅱ)-based metal organic framework

Author

Liu, Wen-bo, Cui, Guan-ning, Wang, Hu, Zhang, Dong-mei, Wu, Rui-xue, Li, Ling, Zhang, Xia, and Fan, Yu-hua

Published

2020

50. Effect of F, V and Mn co-doping on the catalytic performance of TiO2-pillared bentonite in the photocatalytic denitration

Author

WANG, Shu-qin, LI, Jin-meng, and LIU, Wen-bo

Published

2020