Wei Xiong | Quantum Technologies | Best Researcher Award

Published on by High Energy Physics

Assoc. Prof. Dr. Wei Xiong | Quantum Technologies | Best Researcher Award

Head of Department of Physics, Wenzhou University, China

Dr. Wei Xiong is the Head of the Department of Physics at Wenzhou University and a distinguished researcher in quantum optics. With over 58 peer-reviewed publications, 1500+ citations, and a dynamic academic trajectory, he is recognized for pioneering contributions to quantum information science. His research delves into NV spin–magnon interactions, entanglement dynamics, and nonreciprocal quantum mechanisms, pushing the boundaries of theoretical and experimental physics.

👨‍🎓Profile

Google scholar

Scopus

ORCID

🎓 Early Academic Pursuits

Dr. Wei Xiong began his academic journey with a B.Sc. in Physics from Chaohu College, followed by an M.Sc. in Atomic, Molecular, and Optical Physics from Anhui University. He earned his Ph.D. in Theoretical Physics from the prestigious Fudan University. His educational background reflects a strong grounding in both fundamental and applied physics. During his training, Dr. Xiong developed deep expertise in quantum mechanics, optical systems, and magnetic interactions, laying the foundation for his future achievements in quantum optics research.

🧪Professional Endeavors

Dr. Xiong’s career includes critical academic roles, from a Research Assistant at The Hong Kong Polytechnic University, to a Postdoctoral Fellow at the Beijing Computational Science Research Center. He served as Lecturer at Hefei Universityand joined Wenzhou University, where he rose to become a Distinguished Professor. His international exposure, including a short-term academic visit to Zhejiang University, has enriched his global perspective and helped foster interdisciplinary collaborations, essential for cutting-edge quantum research.

🔬 Contributions and Research Focus

Dr. Xiong is acclaimed for his innovative research in quantum optics, notably the first realization of long-distance strong coupling between a single NV spin and magnons, and the demonstration of a magnon-mediated high-fidelity two-qubit Iswap gate. He also proposed a nonreciprocal entanglement mechanism enabled by Kerr nonlinearity in magnons, offering new pathways in quantum communication and sensing. His work bridges quantum theory and spintronics, contributing significantly to quantum information science, hybrid systems, and spin-photon interfaces.

🌐 Impact and Influence

With over 1500 citations on Google Scholar, Dr. Xiong’s work is widely recognized in the international quantum physics community. His studies have influenced next-generation quantum devices, sparking interest in both theoretical physics and experimental applications. As the Head of Department, he fosters academic excellence, encouraging innovation, collaboration, and advanced research culture. His leadership and scientific vision continue to shape young physicists, making a significant impact on research, mentoring, and institutional development.

📊 Academic Cites

Dr. Xiong’s citation index surpasses 1500, reflecting the relevance and influence of his published research. His 58 articles indexed in SCI and Scopus databases demonstrate consistent scholarly output, especially in quantum optics, hybrid quantum systems, and spin-based computing. His most cited works explore the interface of magnonics and quantum coherence, highly regarded by peers in quantum technologies and condensed matter physics. This academic footprint solidifies his position among leading early-career researchers in his field.

🧪 Research Skills 

Dr. Xiong exhibits a rare combination of theoretical modeling, experimental collaboration, and computational simulations in quantum mechanics. His strengths include designing quantum protocols, understanding nonlinear dynamics, and developing models for magnon-based entanglement. He is proficient in using analytical and numerical tools to solve complex problems in quantum field theory and quantum information processing. His collaborative spirit and technical expertise enable productive joint work across multidisciplinary platforms, enhancing research efficiency, depth, and innovation.

👨‍🏫 Teaching Experience

With nearly a decade of academic engagement, Dr. Xiong has taught a wide range of undergraduate and postgraduate courses in quantum mechanics, modern physics, electrodynamics, and advanced theoretical physics. His teaching philosophy emphasizes conceptual clarity, research integration, and student empowerment. At Wenzhou University, he has also guided several master’s and PhD-level research projects, fostering critical thinking and hands-on experience. As a departmental leader, he plays a vital role in curriculum development, faculty mentoring, and academic planning, significantly enhancing the university’s physics education standards.

🏅 Awards and Honors

Dr. Wei Xiong was promoted to Distinguished Professor at Wenzhou University in January 2023, recognizing his excellence in research and leadership. Although his record currently shows no patents or books, his scientific output, editorial role, and collaborations with global institutions stand as a testament to his academic value. His rapid promotion through academic ranks and inclusion in impactful projects mark him as a rising star in quantum optics. Membership in prominent research groups and continuous research support further highlight his dedication and scientific merit.

🌟 Legacy and Future Contributions

Dr. Xiong is poised to make transformative contributions to the fields of quantum optics and hybrid quantum systems. As a scholar, mentor, and leader, he is building a research legacy rooted in fundamental discovery and real-world impact. His long-term vision includes expanding nonreciprocal quantum devices, engaging in cross-border collaborations, and fostering young scientific talent. With continued focus on quantum entanglement mechanisms, he is expected to contribute solutions to emerging challenges in quantum communication and quantum computing, ultimately shaping the next generation of optical and quantum technologies.

Publications Top Notes

Strong and noise-tolerant entanglement in dissipative optomechanics

  • Authors: Jiaojiao Chen, Wei Xiong, Dong Wang, Liu Ye
    Journal: Physical Review A
    Year: 2025

Mechanical Dynamics Around Higher‐Order Exceptional Point in Magno‐Optomechanics

  • Authors: Wen‐Di He, Xiao‐Hong Fan, Ming‐Yue Liu, Guo‐Qiang Zhang, Hai‐Chao Li, Wei Xiong
    Journal: Advanced Quantum Technologies
    Year: 2025

Cavity magnon–polariton interface for strong spin–spin coupling

  • Authors: Ma-Lei Peng, Miao Tian, Xue-Chun Chen, Ming-Feng Wang, Guo-Qiang Zhang, Hai-Chao Li, Wei Xiong
    Journal: Optics Letters
    Year: 2025

Nonreciprocal Microwave-Optical Entanglement in Kerr-Modified Cavity Optomagnomechanics

  • Authors: Ming-Yue Liu, Yuan Gong, Jiaojiao Chen, Yan-Wei Wang, Wei Xiong
    Journal: Chinese Physics B
    Year: 2025

Coherent competition and control between three-wave mixing and four-wave mixing in superconducting circuits

  • Authors: Miao-Xiang Liang, Yu-Xiang Qiu, Hai-Chao Li, Wei Xiong
    Journal: Physical Review A
    Year: 2025

 

 

 

Harshita Srivastava | Quantum Computing | Best Researcher Award

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Ms. Harshita Srivastava | Quantum Computing | Best Researcher Award

Deen Dayal Upadhyaya Gorakhpur University | India

Harshita Srivastava is an accomplished Ph.D. researcher currently pursuing her doctoral studies on Computational Studies of Novel Superalkali Clusters at D.D.U.G.U Gorakhpur. With a robust academic background in Physics and Mathematics, Harshita has made significant strides in computational chemistry and material science, focusing on superalkali clusters and their applications in areas like energy storage, drug design, and carbon dioxide activation.

👨‍🎓Profile

Scopus

Early Academic Pursuits 🎓

Harshita’s academic journey began in the Science Group at the CBSE Board, where she graduated from high school in 2012 and later completed her Intermediate studies in Mathematics in 2014. She earned her B.Sc. in Physics and Mathematics from D.D.U.G.U Gorakhpur in 2017, followed by a Master’s degree in Physics in 2019. Her keen interest in computational studies led her to pursue Ph.D. research at the same institution, where she continues to delve into the world of superalkali clusters.

Professional Endeavors 🔬

Throughout her career, Harshita has demonstrated a commitment to advancing scientific knowledge and contributing to the field of computational chemistry. Her research experience spans a wide array of topics, from superalkalis to the inhibition of SARS-CoV-2, highlighting her ability to apply computational methods to a diverse range of scientific challenges. Her work in understanding the electronic structures of clusters and exploring new materials for applications in energy storage and drug design has established her as an emerging expert in her field.

Contributions and Research Focus 🔍

Harshita’s research is centered around the study of superalkali clusters and their chemical properties, which has implications for a variety of applications. She has contributed to significant publications in top-tier journals like Frontiers in Physics, Chemical Physics Letters, and Journal of the Indian Chemical Society. Her work also extends to material science, specifically studying molecular dynamics, quantum chemistry, and their potential applications in sustainable development. By investigating the interaction of molecules with superalkalis, Harshita has helped to enhance our understanding of nonlinear optical responses, hydrogen storage, and energy-efficient materials.

Impact and Influence 🌍

Harshita’s research is influencing the scientific community, particularly in the realms of superalkalis and nanomaterials. Her work has applications in carbon dioxide activation, hydrogen storage, and the design of strong bases and superbases, which could significantly contribute to addressing global energy and environmental challenges. Additionally, her book chapter contributions on superalkalis, which were published by Taylor & Francis/CRC Press, further demonstrate her scientific influence and commitment to advancing knowledge in her field.

Research Skills 🔧

Harshita possesses advanced research skills, particularly in computational modeling, ab initio studies, and quantum chemical simulations. She is proficient in using a variety of simulation tools such as the Amsterdam Modelling Suite and has experience in docking studies and molecular dynamics simulations. These skills have enabled her to tackle complex scientific problems and make meaningful contributions to the study of novel materials and superalkali chemistry. Her expertise in data analysis and theoretical modeling also positions her as a leader in her research area.

Awards and Honors 🏆

While Harshita is still in the early stages of her career, she has already received significant recognition for her work. Her participation and presentation at conferences such as the International Conference on Nanotechnology and Materials for Energy & Sustainable Development have been well-received. She has also been acknowledged for her contributions to research with certificates and awards from renowned institutions, showcasing her growing reputation in the scientific world.

Legacy and Future Contributions 🔮

Harshita Srivastava’s future in research is bright. With her ongoing work in computational chemistry and superalkali clusters, she is poised to make even more significant contributions to material science, nanotechnology, and sustainability. As she continues to expand her research portfolio, Harshita has the potential to leave a lasting legacy in the scientific community, driving innovations in clean energy, drug design, and environmental solutions. Her work has already laid the foundation for future breakthroughs, and her career is one to watch closely as she continues to push the boundaries of scientific understanding.

Publications Top Notes

BH6+: Revisiting borohydride cation with negatively charged boron and its possible implications for hydrogen storage

  • Authors: Srivastava, A.K., Das, P., Srivastava, H., Chattaraj, P.K.
    Journal: Chemical Physics, 2024

Interaction of N2, O2 and H2 Molecules with Superalkalis

  • Authors: Srivastava, H., Kumar Srivastava, A., Misra, N.
    Journal: ChemistryOpen, 2024

Engineering novel alkalides with superalkali clusters: Ab initio insights into nonlinear optical responses

  • Authors: Srivastava, H., Srivastava, A.K.
    Journal: Molecular Simulation, 2024

Superalkalis in the Design of Strong Bases and Superbases

  • Authors: Srivastava, H., Srivastava, A.K.
    Book Title: Superhalogens and Superalkalis: Bonding, Reactivity, Dynamics and Applications, 2024

Effect of Methyl Substitutions on the Ionization Energy of OH3−n(CH3)n+

  • Authors: Srivastava, H., Tripathi, J.K., Srivastava, A.K.
    Book Title: Springer Proceedings in Materials, 2024

 

 

 

Lilia Tightiz | Quantum Computing | Best Researcher Award

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Assist. Prof. Dr. Lilia Tightiz | Quantum Computing | Best Researcher Award

Assistant Professor at Gachon University, South Korea

Dr. Lilia Tightiz is an accomplished Assistant Professor at Gachon University, Korea, specializing in Computer Science and Engineering. She earned her Ph.D. in Computer Science and Engineering from Sejong University, Korea, in February 2022. With over 15 years of experience in the Electric Power Distribution Industry, Dr. Tightiz has made significant contributions in the design, utilization, and maintenance of electricity distribution grids. She has received numerous accolades, including world-class prizes for her inventions and contributions to the power distribution sector. Dr. Tightiz’s research interests span microgrid energy management, smart grid communication, and quantum machine learning, with a focus on deep reinforcement learning applications in power systems.

Profile🎓

Early Academic Pursuits 🎓

Lilia Tightiz began her academic journey in the field of Computer Science and Engineering, receiving her Ph.D. degree from Sejong University, Korea, in February 2022. Her early academic pursuits were driven by a passion for technological advancements in the electric power distribution sector, which laid the foundation for her future research in microgrid energy management systems and smart grids. Her doctoral research focused on deep, specialized topics within power systems and energy management, helping her build a strong foundation in renewable energy integration and smart grid technologies. With a solid academic background in engineering and computer science, Dr. Tightiz combines practical and theoretical insights to approach modern energy challenges.

Professional Endeavors ⚡

Dr. Tightiz has accumulated over 15 years of professional experience in the Electric Power Distribution Industry. As a Power Distribution Engineer, she contributed to the design, utilization, and maintenance of electricity distribution grids, working on several impactful projects. Her expertise in the sector is demonstrated through her numerous patents and recognition in prestigious forums such as the International Trade Fair for Ideas, Inventions, New Products in Nuremberg, Germany, and the Korean International Women Invention event. These accolades highlight her global influence and her role in transforming the power distribution industry. Dr. Tightiz has also contributed significantly to energy technology exhibitions, such as the Bitgaram International Exposition of Electric Power Technology and the International Invention Fair.

Contributions and Research Focus 🔬

Dr. Tightiz’s research is centered around microgrid energy management, smart grid communication structures, and deep reinforcement learning applications in power systems. She has delved into the intersection of electric vehicles (EVs), charging/discharging scheduling, and quantum machine learning, which are emerging areas in the modern energy landscape. Her work also explores the integration of IEC 61850 and IEC 62439 standards into smart grid systems, ensuring seamless communication and improved system resilience. Dr. Tightiz is particularly focused on optimizing energy efficiency and enhancing grid stability, leveraging cutting-edge technologies like deep reinforcement learning to offer innovative solutions for energy management systems in microgrids.

Impact and Influence 🌍

Dr. Tightiz has had a significant impact on both industry practices and academic research in the power distribution and energy management sectors. Her participation in international trade fairs and expos, along with her patents and world-class prizes, underscores her influence on global energy systems. As an associate editor for the e-Prime (Elsevier) Journal, she has contributed to advancing knowledge and fostering innovation in her field. Her work has been pivotal in bridging the gap between traditional power systems and emerging smart grid technologies, and her contributions are shaping the future of sustainable energy.

Academic Cites 📚

Dr. Tightiz’s research has garnered significant attention, with her work being widely cited in top-tier journals and conferences. Her academic contributions, particularly in deep reinforcement learning and smart grid communication, have positioned her as a leading expert in the field of power systems and energy management. Her efforts to integrate quantum machine learning with power distribution have been recognized as cutting-edge, with increasing citations and collaborations from leading institutions and industry stakeholders.

Technical Skills 🛠️

Dr. Tightiz’s technical expertise spans a wide array of skills and knowledge areas that are critical for modern power systems. She is proficient in deep reinforcement learning algorithms, smart grid communication protocols (IEC 61850, IEC 62439), and the development of microgrid energy management systems. Additionally, she is well-versed in energy optimization techniques, power system modeling, and quantum computing applications in power grids. Her multi-disciplinary skill set makes her a versatile researcher and educator in both engineering and computer science.

Teaching Experience 👩‍🏫

Dr. Tightiz currently serves as an assistant professor at Gachon University, Korea, where she began her academic career in April 2022. Her teaching focuses on cutting-edge topics such as smart grids, power systems, machine learning, and quantum computing in energy applications. Her strong professional background allows her to bring real-world experiences into the classroom, making her lectures highly relevant to current energy challenges. Dr. Tightiz fosters an interactive learning environment, encouraging her students to engage with modern technologies like microgrids and reinforcement learning algorithms to solve pressing energy issues.

Legacy and Future Contributions 🌟

Dr. Tightiz’s legacy is already being shaped by her innovative contributions to the power distribution industry and her leading-edge research in smart grid technologies. Looking forward, she aims to further advance the integration of quantum machine learning in power system optimization and continue her work on microgrids. Her future research will explore sustainable energy solutions and contribute to the global transition towards renewable energy. Dr. Tightiz is also focused on training the next generation of energy scientists and engineers, with a focus on developing innovative technologies that will drive energy sustainability and grid stability.

Top Noted Publications📖

Metaverse-driven smart grid architecture
    • Authors: Lilia Tightiz, L. Minh Dang, Sanjeevikumar Padmanaban, Kyeon Hur
    • Journal: Energy Reports
    • Year: 2024
Enhancing data security and privacy in energy applications: Integrating IoT and blockchain technologies
    • Authors: Hari Mohan Rai, Kaustubh Kumar Shukla, Lilia Tightiz, Sanjeevikumar Padmanaban
    • Journal: Heliyon
    • Year: 2024
Quantum-Fuzzy Expert Timeframe Predictor for Post-TAVR Monitoring
    • Authors: Lilia Tightiz, Joon Yoo
    • Journal: Mathematics
    • Year: 2024
Providing an Intelligent Frequency Control Method in a Microgrid Network in the Presence of Electric Vehicles
    • Authors: Mousa Alizadeh, Lilia Tightiz, Morteza Azimi Nasab
    • Journal: World Electric Vehicle Journal
    • Year: 2024
Implementing AI Solutions for Advanced Cyber‐Attack Detection in Smart Grid
    • Authors: Lilia Tightiz, Rashid Nasimov, Morteza Azimi Nasab, Mohamed Louzazni
    • Journal: International Journal of Energy Research
    • Year: 2024
A cluster-based trusted routing method using fire hawk optimizer (FHO) in wireless sensor networks (WSNs)
    • Authors: Mehdi Hosseinzadeh, Joon Yoo, Saqib Ali, Jan Lansky, Stanislava Mildeova, Mohammad Sadegh Yousefpoor, Omed Hassan Ahmed, Amir Masoud Rahmani, Lilia Tightiz
    • Journal: Scientific Reports
    • Year: 2023
A secure routing approach based on league championship algorithm for wireless body sensor networks in healthcare
    • Authors: Mehdi Hosseinzadeh, Adil Hussein Mohammed, Amir Masoud Rahmani, Farhan A. Alenizi, Seid Miad Zandavi, Efat Yousefpoor, Omed Hassan Ahmed, Mazhar Hussain Malik, Lilia Tightiz
    • Journal: PLOS ONE
    • Year: 2023

 

 

 

 

Wuhong Zhang | Quantum Technologies | Best Researcher Award

Published on by High Energy Physics

Prof. Wuhong Zhang | Quantum Technologies | Best Researcher Award

Associate Professor at Xiamen University, China

Dr. Wuhong Zhang is an Associate Professor in the Department of Physics at Xiamen University. His research interests span quantum optics, photon’s orbital angular momentum (OAM), and quantum computation, with a particular focus on exploiting new degrees of freedom in light for quantum technologies. He has published over 20 research papers in prestigious journals, contributing significantly to quantum correlations, entanglement, and nonlinear optics. His work on OAM and radial momentum of photons has been widely recognized, with several papers highlighted by the editors of journals like Physical Review Letters and Laser & Photonics Review.

Profile🎓

Early Academic Pursuits 📚

Dr. Wuhong Zhang embarked on his academic journey in the field of Physics at Nanyang Normal University, where he earned his undergraduate degree in 2012. His interest in optics and quantum physics began early, laying the foundation for his graduate studies at Xiamen University. He pursued his Master’s degree (2012-2014) and Ph.D. (2014-2017) in Optics and Quantum Optics, where his research on light’s orbital angular momentum (OAM) marked the beginning of his groundbreaking work. Dr. Zhang’s doctoral research focused on the fundamental properties of light and its potential applications in quantum computation, which paved the way for his later contributions to quantum nonlinear optics and structured light.

Professional Endeavors 💼

Following the completion of his Ph.D., Dr. Zhang continued to build his academic career at Xiamen University, where he transitioned from Assistant Professor (2019-2022) to Associate Professor (2022-present) in the Department of Physics. During this time, Dr. Zhang also held important research positions, including a Research Assistant role at Sun Yat-sen University and a Visiting Researcher position at the University of Ottawa in collaboration with the renowned Robert Boyd Group. These experiences allowed him to enhance his expertise in quantum optics, leading to the development of cutting-edge research in quantum correlations and optical parametric down-conversion.

Contributions and Research Focus 🔬

Dr. Zhang’s research focus is centered around the manipulation of photon’s orbital angular momentum (OAM) and radial momentum in the realms of optics and quantum computation. His work in quantum nonlinear optics and the control of quantum correlations within a photonic system is redefining traditional concepts in quantum mechanics. Dr. Zhang’s contributions include free-space remote sensing, quantum remote sensing, and the generation of position-momentum entanglement, all of which have critical implications for the future of quantum information science. His exploration of structured light and entanglement in high-dimensional spaces has led to significant advancements in quantum pattern recognition and optical computing.

Impact and Influence 🌍

Dr. Zhang’s research has significantly impacted the field of quantum optics, with numerous publications in top-tier journals like Physical Review Letters, Optics Express, and Laser & Photonics Review. His highly cited papers have been featured as research highlights and inside cover articles, underlining their global importance. For example, his work on quantum remote sensing and entanglement-assisted ghost imaging has advanced the understanding of how quantum properties can be utilized for high-precision measurements in optical systems. His influence extends beyond academia, as his research is contributing to the development of next-generation quantum technologies such as quantum communication and quantum computing.

Academic Citations 📑

With over 20 high-impact publications, Dr. Zhang’s work is well-recognized in the field of quantum optics. His papers have received significant attention, evidenced by their citation metrics and the numerous research highlights they have garnered in prestigious journals. For example, his paper on optical vortices with a small number of photons published in Laser & Photon. Rev. was selected by the editors for an Inside Cover Paper, and his work on the Einstein-Podolsky-Rosen paradox using radial variables has been featured in Physics. These accolades underscore his growing influence in the academic community, with a strong trajectory toward further recognition in quantum sciences.

Technical Skills 🛠️

Dr. Zhang possesses a comprehensive skill set in both theoretical and experimental optics. His proficiency includes quantum entanglement, nonlinear optics, and photon manipulation techniques such as the generation of entangled photon pairs and quantum correlations. He is adept at utilizing structured light techniques to explore orbital angular momentum and radial momentum in photons. Furthermore, Dr. Zhang is well-versed in optical computing, including the use of twisted light for complex vector convolution. His technical expertise extends to quantum sensing, high-dimensional systems, and deep-learning-based optical pattern recognition, showcasing a well-rounded ability to innovate in cutting-edge areas of quantum physics.

Teaching Experience 👨‍🏫

Dr. Zhang has a solid commitment to teaching and mentoring students at Xiamen University, where he teaches a range of undergraduate and graduate courses, including Optics, Electromagnetics, College Physics, and Physics Experiment. He is known for integrating scientific research enlightenment into his teaching, encouraging students to engage with real-world applications of quantum science and physics. His teaching prowess has been recognized with several awards such as the Second Prize in the Fujian Youth Education Competition (2022) and the Outstanding Young Teachers of University/College in Fujian Province (2022). These accolades speak to his ability to inspire the next generation of scientists and researchers.

Legacy and Future Contributions 🚀

Dr. Zhang’s legacy is already shaping the future of quantum optics and quantum information science. As a leading researcher in the field, his work continues to push the boundaries of what is possible with structured light, quantum correlations, and photon manipulation. Looking ahead, Dr. Zhang aims to further expand his research in quantum computing and quantum communication, working toward real-world applications that will have broad implications for fields ranging from cryptography to medical imaging. His ongoing research projects, such as quantum edge enhancement and quantum pattern recognition, are poised to make groundbreaking contributions to the future of quantum technologies. With continued focus on interdisciplinary collaboration, Dr. Zhang’s work will undoubtedly leave a lasting impact on both academic research and technological innovation in the coming decades.

Top Noted Publications📖

Sorting infrared optical vortices with a nonlinear angular lens
    • Authors: Weiqian Shu, Xiaodong Qiu, Yuan Ren, Wuhong Zhang, Lixiang Chen
    • Journal: Optics Letters
    • Year: 2024
A versatile device for implementing the optical quantum gates in multiple degrees of freedom
    • Authors: Hongming Ke, Shaochen Fang, Wuhong Zhang
    • Journal: Optics & Laser Technology
    • Year: 2024
Polarization Entanglement from Parametric Down-conversion with an LED Pump
    • Authors: Wuhong Zhang, Diefei Xu, Lixiang Chen
    • Journal: Physical Review Applied
    • Year: 2023
Quantum information transfer between a two-level and a four-level quantum systems
    • Authors: Tianfeng Feng, Qiao Xu, Linxiang Zhou, Maolin Luo, Wuhong Zhang, Xiaoqi Zhou
    • Journal: Photonics Research
    • Year: 2022
Non-orthogonal polarization encoding/decoding assisted by structured optical pattern recognition
    • Authors: Shaochen Fang, Yidan Cai, Diefei Xu, Haoxu Guo, Wuhong Zhang, Lixiang Chen
    • Journal: Optics Express
    • Year: 2022
Thermal lens effect with light’s orbital angular momentum
    • Authors: Yuan Li, Wuhong Zhang, Lixiang Chen
    • Journal: Optics Express
    • Year: 2022
Verifying angular-position entanglement by Hardy’s paradox with multisetting high-dimensional systems
    • Authors: Dongkai Zhang, Xiaodong Qiu, Wuhong Zhang, Lixiang Chen
    • Journal: Physical Review A
    • Year: 2022