Jinzhao Li | Civil Engineering | Best Researcher Award

Published on by Physicist Particle

Dr. Jinzhao Li | Civil Engineering | Best Researcher Award

Associated Researcher at Hunan University, China

Jinzhao Li is a dynamic researcher 🧠 specializing in intelligent construction within civil engineering, currently serving as an Associate Researcher at Hunan University. With a keen focus on AI-infused methods and hydrodynamics, Li has contributed extensively to national infrastructure projects, including the Hong Kong-Zhuhai-Macao Bridge 🌉. His academic collaborations span globally renowned institutions such as TU Denmark 🇩🇰, Delft University 🇳🇱, and the University of Tokyo 🇯🇵. With over 50 research publications—including one in Nature Communications Engineering—more than 10 patents, and numerous funded projects, his work blends deep learning, computer vision, and fluid mechanics. Recognized with awards like the Silver Medal 🥈 in the Hunan Postdoctoral Innovation Competition and the China Railway Society Science and Technology Prize, Li exemplifies scientific excellence. His dedication to smart infrastructure and sustainable construction makes him a pivotal contributor to future-ready civil engineering. 🚀

Professional Profile 

Scopus

🎓 Education

Jinzhao Li’s academic journey reflects a powerful blend of engineering rigor and global exposure 🌍. He earned his Bachelor’s degree in Traffic Engineering from Shandong University of Science and Technology (2007–2011), followed by a Ph.D. in Bridge and Tunnel Engineering at Beijing Jiaotong University (2011–2017), under an integrated Master–Ph.D. program. His doctoral work, under the mentorship of Professor Meilan Qi, provided the foundation for his specialization in bridge hydrodynamics and scour processes. To further internationalize his research acumen, he completed joint training at the Technical University of Denmark 🇩🇰, working closely with Professor David R. Fuhrman—an authority in applied ocean research. These cross-continental educational experiences deeply influenced his multi-disciplinary expertise in wave mechanics, AI applications in structural monitoring, and deep-learning physics modeling. 📚 His education solidified not only technical knowledge but also his global research mindset, setting the stage for a versatile, high-impact scientific career. 📖🧠

💼 Professional Experience

Jinzhao Li’s professional path traverses academia, research institutes, and high-impact engineering projects 🏗️. Starting as an Assistant Researcher at the Tianjin Research Institute of Water Transport Engineering (2018–2019), he contributed to national megaprojects like the Shenzhen-Zhongshan Passage and floating tunnel studies. His transition to academia led to a Lecturer role at Shandong University of Science and Technology (2019–2020), where he also served as Deputy Head of Department. Since 2020, he has been advancing frontier research as a Postdoctoral Fellow and now as an Associate Researcher at Hunan University. 🚀 Under collaborative mentorship with National Youth Thousand Talents Professor Xuan Kong, Li steers projects integrating AI, computer vision, and coastal engineering. His work reflects a harmonious blend of theory and fieldwork, evident in his involvement with hydrodynamic model testing, drone-based monitoring systems, and AI-driven structural health diagnostics. 📡 His professional versatility makes him a cornerstone in smart infrastructure R&D.

🧠 Research Interests

Jinzhao Li’s research interests are a fusion of artificial intelligence and civil engineering phenomena 💡. He pioneers in AI intelligent computing, integrating physics-driven deep learning to model real-world complexities such as wave-structure interaction and scour evolution. His work in computer vision-based flow measurement enables high-fidelity monitoring of structural dynamics, especially in disaster-prone flood zones 🌊. As part of his broader vision, he also delves into intelligent fluid dynamics, bridging fluid simulation with machine learning to advance structural resilience. His studies on bridge hydrodynamics and scouring have practical implications for coastal infrastructure safety, while his exploration of flood disaster monitoring employs drones and optical flow algorithms. 📹🔍 Blending neural networks with marine physics, Li pushes the boundary of what intelligent infrastructure can achieve. His focus aligns with smart, sustainable, and responsive design systems—a true intersection of digital intelligence and environmental engineering. 🌐

🏆 Awards and Honors

Jinzhao Li has earned prestigious accolades recognizing both his innovative spirit and technical prowess 🥇. Notably, he was selected for the “Hunan Province Outstanding Postdoctoral Innovation Talent Program”, affirming his place among China’s rising scientific leaders. He secured the Silver Award 🥈 in the First Hunan Postdoctoral Innovation and Entrepreneurship Competition, spotlighting his blend of applied and entrepreneurial science. His technical contributions were further recognized through the China Railway Society Science and Technology Second Prize, a high honor in engineering innovation. Internationally active, Li has served as Guest Editor for the SCI journal Sustainability and is a regular reviewer for top-tier SCI journals. His papers—some co-authored with world-class scientists—have garnered over 900 citations and an H-index of 16, confirming his scientific impact 📊. These honors echo his exceptional integration of AI, hydrodynamics, and vision-based civil engineering.

📚 Publications Top Note 

1. Physics‑preserved graph learning of differential equations for structural dynamics

Authors: (Not specified in search snippet)
Year: 2025
Citations: 0 (appears recent)
Source: Mechanical Systems and Signal Processing
Summary:
This study introduces a novel graph-based learning framework that incorporates the underlying partial differential equations (PDEs) governing structural dynamics directly into the model. By encoding displacement, velocity, and energy dissipation processes via conservation laws within a graph neural network, the model can predict structural responses while adhering to physical laws. It aims to combine data-driven flexibility with physics-based constraints for improved interpretability and generalization under dynamic loads. The approach shows promising accuracy on simulated structural dynamic scenarios.

2. Vehicle Response‑Based Bridge Modal Identification Using Different Time‑Frequency Analysis Methods

Authors: (Not specified in snippet)
Year: 2025
Citations: 5
Source: International Journal of Structural Stability and Dynamics
Summary:
This paper proposes a method leveraging a moving vehicle’s response to identify bridge modal frequencies and mode shapes. It combines Empirical Mode Decomposition (EMD) with advanced time–frequency analysis (e.g. wavelets) to isolate bridge signature from vehicle–track–bridge interactions. Field and simulation results show that this hybrid approach enhances modal identification performance, improving accuracy even amid road surface noise and vehicle dynamics.

3. Full‑field modal identification of cables based on subpixel edge detection and dual matching tracking method

Authors: Jinxin Yi, Xuan Kong, et al.
Year: 2025
Citations: 0
Source: Mechanical Systems and Signal Processing
Summary:
This research introduces a computer vision‑based framework for extracting full‑field cable modal properties in cable-stayed bridges. By applying subpixel edge detection via LSD (Line Segment Detector) on video footage, followed by a dual-matching tracking algorithm, the method captures dense dynamic displacement data. It then derives modal frequencies and employs frequency differences to compute cable tension, avoiding preset tuning parameters. Verified with laboratory and field tests, the approach is robust and accurate.

Conclusion 

In summation, Jinzhao Li stands as a visionary in civil and computational engineering—a scientist bridging traditional hydrodynamics with cutting-edge artificial intelligence 🤖🌊. His career is marked by international collaborations, impactful research outputs, and real-world applications in infrastructure monitoring, disaster prediction, and intelligent design. From postdoctoral recognition in Hunan to Nature-Communications-level publications, his work exemplifies future-focused engineering with societal relevance. Whether optimizing bridge scour prediction through computer vision or leading drone-based flood warning systems, Li’s contributions embody the shift toward data-driven, smart construction ecosystems 🏗️📈. With more than 50 academic publications, 10+ patents, and a robust portfolio of funded research, he is a deserving candidate for elite research honors and fellowships. As AI and civil engineering continue to converge, Jinzhao Li is set to be a torchbearer of the next-generation engineering renaissance. 🌍🔬

Khushboo Singh | Engineering | Best Researcher Award

Published on by Physicist Particle

Dr. Khushboo Singh | Engineering | Best Researcher Award

Research Fellow at University of Technology Sydney, Australia

Dr. Khushboo Singh 🎓🔬 is a Postdoctoral Research Fellow at the University of Technology Sydney 🇦🇺. With 10+ years of experience in academia, defence, and industry, she specializes in high-power millimetre-wave antennas 🚀📡. Her collaboration with the Defence Science and Technology Group (DSTG) has earned her national recognition, including the prestigious Eureka Prize 🏆. Passionate about cutting-edge tech, she also works on space, maritime, and mobile satellite communication systems 🌌🌊📶. A dedicated mentor and leader, Dr. Singh actively supports women in STEM 💪👩‍🔬 while advancing Australia’s research landscape through innovation and excellence 🌟.

Professional Profile:

Scopus

Google Scholar

🔹 Education & Experience 

🎓 Education:

  • 📍 Ph.D. in Electrical & Electronics Engineering | Macquarie University, Australia | 2021

  • 📍 M.Sc. (Research) in Electronics & Communication | LNMIIT, India | 2014 | CPI: 9/10

  • 📍 B.Tech in Electronics & Communication | SHIATS, India | 2012 | CPI: 9.7/10

💼 Experience:

  • 👩‍🔬 Postdoctoral Research Fellow | UTS | Nov 2023 – Present

  • 👩‍🏫 Research Associate | UTS | Nov 2020 – Oct 2023

  • 🌏 Visiting Researcher | IIT-Kanpur | Mar – May 2023

  • 🧠 Technical Researcher | Electrotechnik Pty Ltd. | Nov 2019 – Mar 2020

  • 🎓 Casual Tutor | Macquarie University | 2017, 2024

  • 👩‍🏫 Guest Lecturer | Swami Rama Himalayan University | 2015 – 2016

  • 👩‍🏫 Assistant Professor | Pratap Institute, India | 2014 – 2015

🔹 Professional Development 

Dr. Singh is a passionate leader in research and professional mentoring 🌟. She serves as a mentor in multiple STEM programs 👩‍🔬🤝 including Women in Engineering and WiSR at UTS, encouraging female participation in science and technology 👩‍💻👩‍🔬. As award chair for the 2025 Australian Microwave Symposium 🏅 and a past session organizer for major IEEE and EuCAP conferences, she actively contributes to the global antenna research community 🌐📡. She also provides project supervision, peer reviews, and guidance to students and engineers, playing a key role in shaping future tech talent and research direction 🚀🧑‍🔬.

🔹 Research Focus 

Dr. Singh’s research centers on high-power, metasurface-based millimetre-wave antennas 📡⚡ with beam-steering and in-antenna power-combining features. Her work has major applications in defence, space, maritime, and satellite communications 🛰️🚢. She collaborates with Australia’s Defence Science and Technology Group (DSTG) to design antennas suited for compact, power-constrained environments 🛠️. Her contributions enable better surveillance, radar, and communication systems in mission-critical scenarios 🎯. She is also exploring inter-satellite link antennas and intelligent surfaces for next-gen wireless communication 🌐📶, cementing her role at the intersection of advanced electromagnetics, microwave engineering, and national security defense systems 🛡️.

🔹 Awards & Honors 

🏆 Awards & Honors:

  • 🥇 Winner – 2024 ICEAA – IEEE APWC Best Paper Award

  • 🏅 Winner – 2023 Eureka Prize for Outstanding Science for Safeguarding Australia

  • 👏 Finalist – 2025 AUS SPACE Academic Research Team of the Year

  • 👩‍🚀 Finalist – 2024 ADM Women in Defence (R&D Category)

  • 🧪 Finalist – 2022 UTS Vice-Chancellor’s Award for Research Excellence

  • ⭐ Top 200 Reviewer – IEEE Transactions on Antennas & Propagation (2023)

  • 🥇 Winner – 2019 IEEE NSW Outstanding Student Volunteer

  • 💰 Winner – CHOOSEMATHS Grant by AMSI & BHP Foundation (2017)

  • 🎓 Scholarships – iRTP (2017–2020), LNMIIT Research Stipend (2012–2014)

Publication Top Notes

📘 1. Controlling the Most Significant Grating Lobes in Two-Dimensional Beam-Steering Systems with Phase-Gradient Metasurfaces

  • Authors: K. Singh, M.U. Afzal, M. Kovaleva, K.P. Esselle

  • Journal: IEEE Transactions on Antennas and Propagation

  • Volume/Issue: 68(3), Pages 1389–1401

  • Year: 2019

  • Citations: 86

  • DOI: 10.1109/TAP.2019.2940403

  • Highlights:

    • Introduced techniques to control dominant grating lobes in 2D beam-steering.

    • Employed phase-gradient metasurfaces to steer beams without complex feed networks.

    • Achieved low sidelobe levels and improved directivity.

    • Combined analytical modeling with full-wave electromagnetic simulations.

📗 2. Designing Efficient Phase-Gradient Metasurfaces for Near-Field Meta-Steering Systems

  • Authors: K. Singh, M.U. Afzal, K.P. Esselle

  • Journal: IEEE Access

  • Volume: 9, Pages 109080–109093

  • Year: 2021

  • Citations: 34

  • DOI: 10.1109/ACCESS.2021.3102204

  • Highlights:

    • Focused on near-field applications such as wireless power transfer.

    • Proposed a method to optimize phase response for compact metasurfaces.

    • Improved phase accuracy and minimized aperture size.

    • Demonstrated via simulations and measured prototypes.

📙 3. State-of-the-Art Passive Beam-Steering Antenna Technologies: Challenges and Capabilities

  • Authors: F. Ahmed, K. Singh, K.P. Esselle

  • Journal: IEEE Access

  • Volume: 11, Pages 69101–69116

  • Year: 2023

  • Citations: 28

  • DOI: 10.1109/ACCESS.2023.3285260

  • Highlights:

    • Comprehensive review of passive beam-steering technologies.

    • Covers reconfigurable metasurfaces, mechanical rotation, and tunable materials.

    • Discusses energy efficiency, low-cost manufacturing, and practical limitations.

    • Key insight for researchers targeting 6G, IoT, and wearable tech.

📕 4. Evaluation Planning for Artificial Intelligence-Based Industry 6.0 Metaverse Integration

  • Author: K. Singh

  • Conference: Intelligent Human Systems Integration (IHSI 2023)

  • Year: 2023

  • Citations: 27

  • DOI: 10.1007/978-3-031-28032-0_40

  • Highlights:

    • Discusses AI-driven frameworks for integrating Industry 6.0 with the metaverse.

    • Addresses human-system interaction, digital twins, and smart automation.

    • Proposes an evaluation roadmap for real-time metaverse-industrial synergy.

    • Useful for future cyber-physical systems and smart manufacturing.

📒 5. Accurate Optimization Technique for Phase-Gradient Metasurfaces Used in Compact Near-Field Meta-Steering Systems

  • Authors: K. Singh, M.U. Afzal, K.P. Esselle

  • Journal: Scientific Reports (Nature Publishing Group)

  • Volume: 12, Article 4118

  • Year: 2022

  • Citations: 20

  • DOI: 10.1038/s41598-022-08057-8

  • Highlights:

    • Developed a precise numerical optimization technique for metasurface design.

    • Reduced phase errors, enabling high-accuracy near-field beam control.

    • Achieved better performance in compact and portable systems.

    • Practical for radar, medical imaging, and wireless power applications.

Conclusion

Dr. Khushboo Singh exemplifies the qualities of an outstanding researcher — innovative, impactful, and committed to scientific excellence. Her exceptional track record in antenna technology for defense and space applications, combined with her leadership in mentoring and research supervision, makes her a standout candidate for the Best Researcher Award. Her research is not only scientifically robust but also socially and nationally significant, particularly in safeguarding technological frontiers of Australia.

She is a role model for aspiring researchers, especially women in STEM, and a worthy recipient of such an honor.

Ali Darvish Falehi | Engineering | Excellence in Researcher Award

Published on by Physicist Particle

Assoc. Prof. Dr. Ali Darvish Falehi | Engineering | Excellence in Researcher Award

Dr. Darvish Falehi at Islamic Azad University, Iran

Ali Darvish Falehi is a distinguished academic and professional in the field of Electrical Power Engineering. With a Ph.D. and Post-Ph.D. from Shahid Beheshti University, he ranks among the world’s top 2% scientists as listed by Stanford University in 2020. He is currently an Assistant Professor at Iran Islamic Azad University, a technical expert at Iran North Drilling Company, and the Chairman of the R&D Board at HICOBI Company. He has delivered keynote speeches at several international conferences and holds numerous patents. His contributions extend to supervising over 50 theses and reviewing for prestigious journals. 🌟🔬📚

Professional Profile:

Google Scholar

Education and Experience:

  • Post-Ph.D. & Ph.D. in Electrical Power Engineering, Shahid Beheshti University (First Class Honors) 🎓

  • Ranked among the world’s top 2% scientists by Stanford University in 2020 🌍

  • Chairman of R&D Board at HICOBI Company 🏢

  • Assistant Professor at Iran Islamic Azad University 👨‍🏫

  • Technical Expert at Iran North Drilling Company ⚙️

  • Main Speaker at national and international conferences 🎤

  • Reviewer for prestigious journals (IEEE, Elsevier, Springer) 📖

  • Supervisor & Adviser for 50+ M.Sc. and Ph.D. theses 📝

  • TOEFL-PBT score: 630 (Writing Score: 6) 🏆

  • Patents and medals at invention festivals in Iran, South Korea, and Romania 🏅

Professional Development: 

Ali Darvish Falehi has continuously developed his professional expertise by participating in global conferences and providing thought leadership as a main speaker and reviewer for high-impact journals such as IEEE and Elsevier. His dedication to research has led him to supervise over 50 graduate and doctoral theses, contributing to the academic growth of the next generation of engineers. He is also deeply involved in the industrial sector, where he serves as a technical expert for Iran North Drilling Company and leads the R&D board at HICOBI Company, driving innovation and technology forward. His work bridges academia and industry, enhancing both fields. 🔧🌐📊

Research Focus:

Ali Darvish Falehi’s research is centered around Electrical Power Engineering, with particular attention to energy systems, power distribution, and renewable energy solutions. His work aims to optimize power engineering technologies, focusing on improving energy efficiency and sustainability. He is known for his contributions to the development of advanced electrical systems and has been actively involved in creating patented innovations. His expertise in power engineering is complemented by his role as a technical expert, where he advises on industrial applications of electrical power systems. His research seeks to solve complex energy challenges, aligning with global sustainability goals. ⚡🌱🔋

Awards and Honors:

  • Ranked among the world’s top 2% scientists by Stanford University (2020) 🌍

  • Chairman of the R&D Board at HICOBI Company 🏢

  • Main Speaker at several international conferences 🎤

  • Reviewer for leading ISI journals like IEEE, Elsevier, Springer 📚

  • Supervisor & Adviser for 50+ M.Sc. and Ph.D. theses 📝

  • TOEFL-PBT Score: 630 🏆

  • Patents and medals from invention festivals in Iran, South Korea, and Romania 🏅

Publication Top Notes

  1. “An innovative optimal RPO-FOSMC based on multi-objective grasshopper optimization algorithm for DFIG-based wind turbine to augment MPPT and FRT capabilities” (2020)

    • Authors: A.D. Falehi

    • Journal: Chaos, Solitons & Fractals

    • Summary: This paper proposes an innovative control strategy using a multi-objective Grasshopper Optimization Algorithm (GOA) to enhance the MPPT and Fault Ride Through (FRT) capabilities of DFIG-based wind turbines. The use of Fractional-Order Sliding Mode Control (FOSMC) is central to this work.

  2. “Promoted supercapacitor control scheme based on robust fractional-order super-twisting sliding mode control for dynamic voltage restorer to enhance FRT and PQ capabilities of DFIG-based wind turbines” (2021)

    • Authors: A.D. Falehi, H. Torkaman

    • Journal: Journal of Energy Storage

    • Summary: This paper focuses on enhancing the FRT and Power Quality (PQ) capabilities of DFIG-based wind turbines. The authors propose a robust fractional-order control scheme for supercapacitors integrated with a Dynamic Voltage Restorer (DVR).

  3. “LVRT/HVRT capability enhancement of DFIG wind turbine using optimal design and control of novel PIλDμ-AMLI based DVR” (2018)

    • Authors: A.D. Falehi, M. Rafiee

    • Journal: Sustainable Energy, Grids and Networks

    • Summary: This work aims to enhance the Low Voltage Ride Through (LVRT) and High Voltage Ride Through (HVRT) capabilities of DFIG wind turbines by optimizing the design and control of a novel DVR based on a PIλDμ-AMLI (Proportional-Integral-Derivative) controller.

  4. “Enhancement of DFIG-wind turbine’s LVRT capability using novel DVR based odd-nary cascaded asymmetric multi-level inverter” (2017)

    • Authors: A.D. Falehi, M. Rafiee

    • Journal: Engineering Science and Technology, an International Journal

    • Summary: This paper explores improving the LVRT capability of DFIG wind turbines by integrating a novel Dynamic Voltage Restorer (DVR) system with an odd-nary cascaded asymmetric multi-level inverter.

  5. “Neoteric HANFISC–SSSC based on MOPSO technique aimed at oscillation suppression of interconnected multi-source power systems” (2016)

    • Authors: A.D. Falehi, A. Mosallanejad

    • Journal: IET Generation, Transmission & Distribution

    • Summary: This paper addresses the oscillation suppression in interconnected multi-source power systems using a Hybrid Active Networked Flexible Integrated Supply Chain (HANFISC)-Static Synchronous Series Compensator (SSSC) controlled by the Multi-Objective Particle Swarm Optimization (MOPSO) technique.

Conclusion:

Ali Darvish Falehi is undoubtedly a deserving candidate for the Excellence in Researcher Award. His combination of academic excellence, significant contributions to electrical power engineering, leadership in both academia and industry, and his global recognition positions him as a standout figure in his field. His ability to balance research with innovation, along with his dedication to mentoring future researchers, makes him an exemplary choice for this prestigious award.

Yun Zhao | Engineering | Best Researcher Award

Published on by Physicist Particle

Assoc. Prof. Dr. Yun Zhao | Engineering | Best Researcher Award

Yun Zhao at Northwest Normal University, China

Dr. Yun Zhao 🎓 is an Associate Professor at the College of Physics and Electronic Engineering, Northwest Normal University 🏫, since 2020. He earned his Ph.D. in Materials Science and Engineering 🧪 from the Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences 🇨🇳, in 2020. Shortly after, he joined the Ningbo Institute of Materials Technology and Engineering 🔬 as a postdoctoral researcher. His work focuses on thin film photodetectors 📸 and semiconductor devices 💡. Dr. Zhao is passionate about next-gen optoelectronics and is actively contributing to innovation in functional materials and device engineering 🚀.

Professional Profile:

Orcid

Scopus

🎓 Education & Experience 

  • 📚 Ph.D. in Materials Science and Engineering, Lanzhou Institute of Chemical Physics, CAS – 2020

  • 🧑‍🏫 Postdoctoral Researcher, Ningbo Institute of Materials Technology and Engineering, CAS

  • 👨‍🏫 Associate Professor, College of Physics and Electronic Engineering, Northwest Normal University – Since 2020

📈 Professional Development 

Dr. Yun Zhao continuously engages in academic and research development through national and institutional collaborations 🤝. His postdoctoral work at the prestigious Ningbo Institute of CAS sharpened his experimental techniques and deepened his expertise in advanced semiconductors ⚙️. As an associate professor, he mentors young researchers 👨‍🔬 and collaborates on interdisciplinary projects across optics, electronics, and nanotechnology 🔍. He regularly attends academic conferences, publishes in reputed journals 📄, and reviews scientific manuscripts. His dedication to professional growth ensures he stays at the forefront of innovation in functional materials and optoelectronic devices 🌐.

🔬 Research Focus 

Dr. Yun Zhao’s research primarily revolves around thin film photodetectors 📸 and semiconductor devices ⚡. His focus lies in designing and fabricating new materials with enhanced sensitivity, stability, and performance for light-sensing technologies 🌞. He explores emerging materials such as perovskites and nanostructures 🌱 for integration into flexible and wearable electronics 🧤. His work bridges the gap between material science and applied electronics, aiming to revolutionize future optoelectronic systems 🔋. The end goal of his research is to contribute to high-performance, low-cost, and energy-efficient devices for real-world applications 🚗📱.

🏆 Awards and Honors 

  • 🎖️ Ph.D. fellowship from the Chinese Academy of Sciences

  • 🏅 Postdoctoral appointment at Ningbo Institute of Materials Technology and Engineering (CAS)

  • 🏆 Recognized for outstanding research contributions in thin film photodetectors

  • 📜 Multiple peer-reviewed publications in reputed international journals

Publication Top Notes

1. Understanding Proton Radiation-Induced Degradation Mechanisms in Cu₂ZnSn(S,Se)₄ Kesterite Thin-Film Solar Cells

Journal: Solar Energy
Date: May 2025
DOI: 10.1016/j.solener.2025.113450
Summary:
This study investigates how proton radiation affects the stability and performance of Cu₂ZnSn(S,Se)₄ (CZTSSe) thin-film solar cells. Proton radiation is relevant for space applications where solar cells are exposed to high-energy particles. The paper likely explores:

  • Changes in carrier lifetimes and defect states post-irradiation.

  • Structural or compositional changes in the absorber layer.

  • Strategies to mitigate degradation for improved radiation tolerance.

2. Multifunctional Artificial Electric Synapse of MoSe₂-Based Memristor toward Neuromorphic Application

Journal: The Journal of Physical Chemistry Letters
Date: February 6, 2025
DOI: 10.1021/acs.jpclett.4c03353
Summary:
This article presents a MoSe₂-based memristor designed to emulate biological synapses. The work focuses on neuromorphic computing, highlighting:

  • Synaptic plasticity behaviors (e.g., potentiation/depression).

  • Multifunctionality (possibly electrical + optical control).

  • Performance metrics like switching speed, retention, and endurance.

3. Exploring the Promoting Effect of Lanthanum Passivation on the Photovoltaic Performance of CZTSSe Solar Cells

Journal: The Journal of Chemical Physics
Date: December 21, 2024
DOI: 10.1063/5.0244645
Summary:
This paper studies how lanthanum (La) passivation enhances CZTSSe solar cell efficiency. Key aspects likely include:

  • Reduction in defect densities at grain boundaries or interfaces.

  • Improvements in open-circuit voltage and fill factor.

  • Insights into La’s role in modifying electronic structure or surface chemistry.

4. Electrical-Light Coordinately Modulated Synaptic Memristor Based on Ti₃C₂ MXene for Near-Infrared Artificial Vision Applications

Journal: The Journal of Physical Chemistry Letters
Date: August 29, 2024
DOI: 10.1021/acs.jpclett.4c02281
Summary:
This research showcases a Ti₃C₂ MXene-based memristor that responds to both electrical and light inputs, mimicking the retina for near-infrared vision. Highlights include:

  • Dual-mode modulation (electrical and optical).

  • Application in neuromorphic visual systems.

  • Spectral response analysis and synaptic behavior simulation.

5. Multicolor Fully Light-Modulated Artificial Synapse Based on P-MoSe₂/PxOy Heterostructured Memristor

Journal: The Journal of Physical Chemistry Letters
Date: August 29, 2024
DOI: 10.1021/acs.jpclett.4c01980
Summary:
This study introduces a heterostructured memristor combining P-doped MoSe₂ and PxOy, enabling light-tuned synaptic responses. Likely contributions:

  • Multicolor light sensitivity for multi-channel processing.

  • Photonic modulation of conductance states.

  • Integration prospects for optical neuromorphic systems.

Conclusion

Dr. Yun Zhao is highly suitable for the Best Researcher Award, particularly in categories related to emerging materials, device physics, or engineering sciences. His rapid academic progression, focused and relevant research in photodetectors and semiconductors, and training at top-tier institutions within the Chinese Academy of Sciences establish him as a promising and impactful researcher. Recognition through such an award would be both meritorious and motivating for his continued contributions to the field.