Sanjay Kumar Sharma – Analytical Method Development – Best Researcher Award 

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Mr. Sanjay Kumar Sharma began his academic career with a strong inclination toward chemistry and pharmaceutical sciences. He completed his B.Sc. in Chemistry from Maharaja Ranjit Singh College under DAVV University in 2010, followed by a Master’s in Pharmaceutical Chemistry from VIT University in 2012, achieving an impressive aggregate of 88%. His early academic success set the foundation for his keen interest in  Analytical Method Development, motivating him to pursue his PhD at St. Peter’s University, Chennai, which he enrolled in during 2023. From his formative education, he demonstrated a consistent focus on practical and theoretical aspects of chemical sciences, particularly analytical chemistry.

💼 Professional Endeavors

Mr. Sharma's professional journey spans over a decade across leading pharmaceutical companies such as Biocon, PI Industries, Anthem Biosciences, Sami Labs, and Zenfold Sustainable Technologies, where he currently serves as Deputy Manager (Team Lead). In each of these roles, he played a pivotal part in  Analytical Method Development using advanced instrumentation techniques such as HPLC, UPLC, LCMS, UV spectrophotometry, and GC. His career reflects a progression from a bench chemist to a leadership role, where he now manages teams, ensures analytical compliance, optimizes workflows, and handles regulatory support. He has trained and mentored analytical scientists while leading cross-functional collaborations.

🔬 Contributions and Research Focus

Mr. Sharma has made substantial contributions to  Analytical Method Development, focusing on pharmaceuticals, APIs, intermediates, and impurities. His core strengths lie in designing robust methods for related substance determination, cleaning validations, chiral separations, and process validations. His work notably includes developing UV-based methods for cost-saving and optimizing run time by replacing traditional GC/HPLC techniques with innovative detection strategies like RID and ELSD. His deep involvement in the qualification of PGIs, NCOs, and UV-inactive compounds reflects his analytical precision and strategic problem-solving capabilities.

🌍 Impact and Influence

Over the years, Mr. Sharma's analytical strategies have significantly influenced cost-reduction and efficiency within major pharmaceutical R&D environments. His leadership in  Analytical Method Development has directly contributed to quality assurance, regulatory compliance, and operational excellence. His problem-solving abilities have not only streamlined internal laboratory operations but have also been crucial in managing customer queries and supporting regulatory submissions. Awards such as the Certificate of Excellence at Biocon and his recognition in Analytical Development Quizzes further underscore his industry impact.

🏆Academic Cites

While Mr. Sharma's work is primarily industrial, he has demonstrated scholarly engagement through participation in academic quizzes and international chemistry events such as the International Year of Chemistry quiz at VIT. He has completed training programs from global leaders like Thermo Fisher Scientific and Shimadzu, enhancing his capabilities in instrumentation and method development. His involvement in UNESCO and UN Information tests during his school years is a testament to his early global outlook on science and research. His practical knowledge in  Analytical Method Development is disseminated through training programs for interns and new team members.

🌟 Legacy and Future Contributions

With a rich background in method optimization and quality systems, Mr. Sharma is poised to continue his legacy in  Analytical Method Development. His ongoing doctoral research, combined with his hands-on experience, is likely to bridge academic research and industrial application, contributing to the development of novel analytical solutions. He is expected to continue mentoring scientists, advancing green chemistry techniques to reduce chemical consumption, and contributing to sustainable pharmaceutical manufacturing.

📝Analytical Method Development

Mr. Sanjay Kumar Sharma has continuously demonstrated excellence in  Analytical Method Development across leading pharma organizations. His expertise in  Analytical Method Development has enabled significant innovations in drug analysis, impurity profiling, and method transfer. Going forward, his work will remain instrumental in the evolution of  Analytical Method Development frameworks within regulated and sustainable R&D environments.

Notable Publication

📝Nitro-driven Electrophilicity: A Combined HPLC and Computational Study of Para-nitrophenylethylamine and Its Impurities

Authors: Sanjay Kumar Sharma, Sayeeda Sultana, Vivek Sharma, Osvaldo Yañez, Plinio De Los Santos Cantero-López

Journal: Journal of Liquid Chromatography and Related Technologies, 2025

Citations: 0

Wendong Gai – Flight Control – Best Researcher Award 

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Prof. Wendong Gai embarked on his academic journey with a strong focus on control engineering and aviation systems. Early in his academic life, he demonstrated a passion for autonomous systems, particularly unmanned aerial vehicles (UAVs). His rigorous academic training laid a robust foundation in flight dynamics, control theory, and intelligent optimization techniques, setting the stage for his impactful career in Flight Control and UAV technologies.

💼 Professional Endeavors

Throughout his career, Prof. Wendong Gai has taken on significant roles in both research and education. He has led critical projects such as "Closed-loop Adaptive Control Allocation with Prescribed Performance for Aircraft with Multiple Actuators" funded by the National Natural Science Foundation of China (2017–2019) and "Dynamic Event-Triggered Multi-UAV Formation Fault Detection" funded by the Shandong Provincial Natural Science Foundation (2024–2026). His professional endeavors consistently focus on Flight Control systems, fault diagnosis, fault-tolerant control, and intelligent optimization, bridging theoretical research with real-world applications in UAV systems.

🔬 Contributions and Research Focus

Prof. Gai’s research focus revolves around Flight Control of UAVs, fault diagnosis and tolerant control, as well as intelligent control strategies. His contributions include the development of dynamic event-triggered control frameworks, novel optimization algorithms like the Hybrid Grey Wolf Optimizer for UAV path planning, and innovative reinforcement learning-based optimization methods. Through his pioneering work, he has enhanced the efficiency, robustness, and safety of autonomous UAV operations, particularly in complex environments requiring collision avoidance and fault tolerance.

🌍 Impact and Influence

Prof. Wendong Gai has had a significant impact on the field of Flight Control and UAV research globally. His high-quality academic publications in top-tier journals such as IEEE Transactions on Instrumentation and Measurement, Knowledge-Based Systems, and Applied Soft Computing showcase his technical leadership. His methods for fast finite-time convergent guidance laws and disturbance rejection control strategies are being increasingly adopted in UAV systems worldwide, influencing both academic research and industrial practice.

🏆Academic Cites

Prof. Gai's scholarly work has earned substantial academic citations, highlighting the widespread recognition and application of his research. His papers on fault detection optimization, hybrid grey wolf optimizer algorithms, and collision avoidance strategies have become foundational references for researchers exploring advanced UAV control systems and Flight Control strategies. His academic citations reflect the depth, innovation, and practical relevance of his contributions to the UAV and control engineering communities.

🌟 Legacy and Future Contributions

As a visionary leader in Flight Control, Prof. Wendong Gai’s legacy is firmly rooted in his innovative approaches to UAV autonomy and resilience. Moving forward, he is expected to drive even greater advancements in dynamic event-triggered control systems, fault-tolerant flight architectures, and intelligent swarm behaviors. His mentorship of young researchers and leadership in major national projects ensure that his contributions will continue to shape the future of UAV technologies and autonomous flight systems for years to come.

📝Flight Control

Prof. Wendong Gai’s research achievements in Flight Control have fundamentally improved UAV system performance and safety. His pioneering work in Flight Control optimization, fault diagnosis, and adaptive guidance has set new standards in the industry. The future of autonomous aviation is certain to be influenced by his continuous contributions to Flight Control systems and intelligent optimization methods.

Notable Publication

📝A Modified VSG Control Scheme with Transient Damping to Improve Transient and Frequency Stability

Authors: Wendong Gai, Zhiru Wang, Gang Jing, Guilin Zhang

Type: Conference Paper

Citations: 0

Focus: Proposes a modified Virtual Synchronous Generator (VSG) control strategy with added transient damping, aiming to enhance transient and frequency stability in power systems.

📝Event-Triggered Hi/H∞ Optimization Approach to Distributed Fault Detection for Multi-Agent Systems

Authors: Wendong Gai, Yaxin Sun, Guilin Zhang, Maiying Zhong

Journal: Asian Journal of Control, 2025

Citations: 0

Focus: Introduces an event-triggered H-infinity (Hi/H∞) optimization framework for distributed fault detection among multi-agent systems, enhancing robustness and fault tolerance.

📝Disturbance-Observer-Based Distributed Formation Control for Multi-Agent Systems with Dynamic Event-Triggered Mechanism

Authors: Wendong Gai, Yuqi Zheng, Yang Yang, Guilin Zhang, Jing Zhang

Journal: International Journal of Systems Science, 2025

Citations: 0

Focus: Focuses on distributed formation control for multi-agent systems using disturbance observers and dynamic event-triggering to efficiently maintain formations under disturbances.

📝Consensus-Based Control for Power Sharing and Voltage/Frequency Recovery in Microgrids

Authors: Jing Zhang, Mengfei Sun, Wendong Gai, Guilin Zhang

Type: Conference Paper

Citations: 0

Focus: Presents a consensus-based control approach for effective power sharing and recovery of voltage/frequency in microgrid operations, enhancing system resilience.

Chaoqun Dong – Soft Materials – Best Researcher Award 

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Dr. Chaoqun Dong’s academic journey began with his undergraduate studies at the University of Jinan, China, where he earned a BS in Materials Science and Engineering. His outstanding performance earned him the Best Thesis Award and the Merit Students Award, recognizing his early promise in the field of materials science. Driven by a passion for innovation in materials, he continued his academic pursuits at Shandong University, China, where he obtained a Master’s in Materials Science and Engineering, under the guidance of Prof. Zhonghua Zhang. During this time, he was awarded several prestigious distinctions, including the Outstanding Graduate Award and the Zhaoyang Scholarship from Shandong Province.

💼 Professional Endeavors

Dr. Dong’s professional journey has been marked by remarkable academic and research positions in renowned institutions. After completing his MS, he pursued a PhD at École Polytechnique Fédérale de Lausanne (EPFL), Switzerland, under the mentorship of Prof. Fabien Sorin, where he conducted cutting-edge research in the field of soft materials. Dr. Dong has further enriched his expertise as a Postdoctoral Researcher at EPFL and as a Marie Skłodowska-Curie Postdoctoral Fellow at the University of Cambridge, UK, where he worked in the Electrical Engineering Division, Department of Engineering, under the guidance of Prof. George G. Malliaras. He is currently poised to join the University of Cambridge as an Assistant Professor in the Department of Mechanical Engineering in 2025.

🔬 Contributions and Research Focus

Dr. Chaoqun Dong’s research focus lies primarily in the field of soft materials, with significant contributions to their understanding, development, and applications. His work encompasses the study of advanced materials in various domains, including flexible electronics, bioelectronics, and other soft matter applications. By investigating the mechanical, electrical, and optical properties of soft materials, Dr. Dong has contributed to innovations that bridge materials science and engineering, fostering advancements in wearable technology and medical devices. His expertise in soft matter has been instrumental in advancing new concepts and models that push the boundaries of this interdisciplinary field.

🌍 Impact and Influence

Dr. Dong’s influence in the field of soft materials extends beyond academia. Through his work, he has helped to propel the development of next-generation technologies in wearable devices and biocompatible materials. His research has attracted global attention, particularly in areas such as flexible sensors and bioelectronics, and his contributions continue to inspire further exploration in these fields. Dr. Dong is an active participant in international research communities, having received numerous awards, including the prestigious Electrical Engineering Outreach Award from the University of Cambridge and the National Scholarship from the Ministry of Education of China. He has also been invited to attend the Global Young Scientists Summit (GYSS) in Singapore in 2025, a testament to his standing in the scientific community.

🏆Academic Cites

Dr. Dong’s scholarly work has garnered significant recognition in academic circles. His publications on soft materials are widely cited, reflecting their relevance and impact on ongoing research and technological developments. His innovative approaches to understanding the properties and behaviors of soft materials have led to a broad dissemination of knowledge, with his work laying a foundation for future breakthroughs in materials science. The high citation count of his research attests to the global recognition of his contributions and their importance in advancing the field.

🌟 Legacy and Future Contributions

Looking ahead, Dr. Chaoqun Dong is set to make even greater contributions to the field of soft materials. His appointment as an Assistant Professor at the University of Cambridge marks the beginning of an exciting new chapter in his career, where he is expected to continue advancing research in this field. His legacy will likely be defined by his groundbreaking research, his influence on the development of wearable and biomedical technologies, and his commitment to mentoring the next generation of scientists. Dr. Dong’s continued exploration of soft materials promises to revolutionize applications in fields such as healthcare, robotics, and electronics, ensuring a lasting impact on both academic and industrial fronts.

📝Soft Materials

Dr. Chaoqun Dong’s expertise in soft materials has positioned him as a leader in the field, with his research contributing to significant advancements in the understanding and application of these materials. His work has paved the way for future developments in soft materials, especially in wearable technology, bioelectronics, and flexible sensors. With his ongoing research efforts and the anticipated launch of new projects at the University of Cambridge, Dr. Dong’s legacy in soft materials is set to grow, impacting both academic research and practical applications worldwide.

Notable Publication

📝Toolkit for Integrating Millimeter-Sized Microfluidic Biomedical Devices with Multiple Membranes and Electrodes

Authors: Xudong Tao, Tobias E. Naegele, Etienne Rognin, Ronan Daly, George G. Malliaras

Journal: Microsystems and Nanoengineering, 2025

Citations: 1

📝Recent Advances in Stimuli-Responsive Materials for Intelligent Electronics

Authors: Siyao Chen, Hongqiu Wei, Cheng Lin, Chaoqun Dong, Xue Wan

Journal: Full text unavailable

Citations: 0

📝Cleanroom-Free Toolkit for Patterning Submicron-Resolution Bioelectronics on Flexibles

Authors: Xudong Tao, Alejandro Carnicer-Lombarte, Antonio Domínguez-Alfaro, Sohini Kar-Narayan, George G. Malliaras

Journal: Small, 2025

Citations: 0

Cheng Cai – Biomass Molecules – Best Researcher Award

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Mr. Cheng Cai began his academic journey at the Wuhan Institute of Technology, majoring in Chemical Engineering and Technology, where he completed his Bachelor's degree in 2014. He then pursued a Doctorate at the South China University of Technology, specializing in Chemical Engineering, and graduated in 2020. His early focus on chemical processes and materials laid a strong foundation for his future contributions to the conversion and application of biomass molecules. This early academic excellence was supplemented by his postdoctoral research at the prestigious Dalian Institute of Chemical Physics, Chinese Academy of Sciences.

💼 Professional Endeavors

Mr. Cheng Cai has gained valuable professional experience through his postdoctoral work at the Institute of Chemical Physics, Chinese Academy of Sciences in Dalian (2021–2023), where he focused on advancing the conversion and application of biomass molecules in various industrial processes. Since March 2023, he has served as an Associate Professor at the Institute of Biomass Engineering, South China Agricultural University. His expertise is recognized internationally, and he has collaborated with renowned institutions like the United States Department of Agriculture's Forest Products Laboratory, contributing to the development of new methodologies for biomass utilization and enzyme immobilization.

🔬 Contributions and Research Focus

Mr. Cai’s research centers on the chemical catalytic conversion of lignocellulose, enzyme immobilization, and the preparation and application of lignin and cellulosic materials. His work has significantly advanced the understanding and technology related to the conversion of biomass molecules, particularly focusing on enhancing the efficiency of lignocellulosic biomass in bioenergy and chemical production. His notable contributions include exploring the role of lignin in enzymatic hydrolysis, developing new methods for enzyme recovery, and improving the sustainable utilization of biomass molecules for industrial applications.

🌍 Impact and Influence

Mr. Cheng Cai's research has had a profound impact on the field of biomass engineering. His work in the conversion and application of biomass molecules has helped shape modern approaches to sustainable energy and materials production. His findings have influenced both academic research and industrial practices, particularly in improving the efficiency of biomass processing. Through his collaborations and publications, Mr. Cai has established himself as a leading figure in the field, contributing to global discussions on sustainable biomass utilization and the environmental benefits of efficient biomass conversion.

🏆Academic Cites

Mr. Cai's scholarly work has been widely cited in top-tier journals, underscoring the significance of his contributions to the conversion and application of biomass molecules. His research has sparked further exploration into sustainable biomass processing techniques and enzyme recovery methods. His papers, particularly on lignin and cellulosic materials, are frequently referenced by researchers in the field, attesting to their importance and impact in advancing knowledge about biomass-based technologies.

🌟 Legacy and Future Contributions

Looking ahead, Mr. Cheng Cai’s future contributions promise to further transform the conversion and application of biomass molecules into more efficient and sustainable processes. His ongoing projects, particularly those funded by the National Natural Science Foundation of China, aim to enhance the application of lignocellulosic biomass and enzyme immobilization technologies. As he continues to develop innovative solutions for biomass processing, Mr. Cai is poised to leave a lasting legacy in the field of biomass engineering, advancing the transition to more sustainable and economically viable bio-based industries.

📝Conversion and Application of Biomass Molecules

Mr. Cheng Cai's work has centered on the conversion and application of biomass molecules, focusing on how to optimize the use of lignocellulosic materials and enzymes for sustainable industrial processes. His research contributes significantly to the field by enhancing the efficiency of biomass molecules conversion and laying the groundwork for future developments in bioenergy and materials. As he continues to explore innovative methods for biomass utilization, his expertise in the conversion and application of biomass molecules will undoubtedly influence the next generation of engineers and researchers in this critical field.

Notable Publication

📝Oxidative Catalytic Fractionation of Lignocellulose Enhanced by Copper-Manganese-Doped CeO2

Authors: Yuting Zhu, Ning Li, Huifang Liu, Junju Mu, Feng Wang

Journal: ACS Catalysis, 2024

Citations: 2

📝Changing the Role of Lignin in Enzymatic Hydrolysis for a Sustainable and Efficient Sugar Platform

Authors: Cheng Cai, Chaofeng Zhang, Ning Li, Junyong Zhu, Feng Wang

Journal: Full text unavailable

Citations: 44

Hyoungsoo Kim – Experimental Fluid Mechanics – Best Researcher Award 

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Professor Hyoungsoo Kim's academic journey began with a deep foundation in mechanical engineering, culminating in his Ph.D. in Mechanical, Maritime, and Materials Engineering from Delft University of Technology, Netherlands. His thesis on "Moving Liquid Droplets with Inertia: Experiment, Simulation, and Theory" explored fundamental principles of fluid mechanics, setting the stage for his future contributions to experimental fluid mechanics. His earlier academic endeavors, including an M.S. in Mechanical Engineering from the Korea Advanced Institute of Science and Technology (KAIST) and a B.S. in Mechanical Engineering from Kumoh National Institute of Technology, shaped his solid expertise in fluid dynamics and experimental methodologies, ultimately leading him to significant research positions in top-tier institutions worldwide.

💼 Professional Endeavors

Prof. Hyoungsoo Kim’s professional career has seen him rise to key academic and research positions, currently serving as an Associate Professor at KAIST's Department of Mechanical Engineering. He has held multiple prestigious roles, including a Visiting Scholar position at Harvard University and Associate Research Scholar at Princeton University. His professional work in experimental fluid mechanics has involved pioneering contributions to understanding complex fluid dynamics, interfacial instabilities, and microfluidic applications. Prof. Kim’s roles at these world-leading institutions allowed him to refine his research, deepen collaborations, and advance his field.

🔬 Contributions and Research Focus

Prof. Kim's research is focused on experimental fluid mechanics, with an emphasis on complex fluid flows, liquid metal dynamics, and interfacial phenomena. He has made notable advancements in understanding the behaviors of liquid droplets, the interaction of complex fluids, and Marangoni effects in both micro and macroscales. His work includes novel contributions to the development of real-time gas visualization systems, mobile chemical and biological gas detection devices, and technologies for improving the performance of next-generation semiconductors and energy-efficient mixing techniques. His research has direct applications in industries such as semiconductors, energy, and medical technologies.

🌍 Impact and Influence

The impact of Prof. Hyoungsoo Kim’s research on experimental fluid mechanics extends beyond academia. His groundbreaking work has influenced a range of industries, from materials science to energy, with specific advancements in improving manufacturing processes and medical diagnostics. Prof. Kim's research in fluid dynamics and microfluidic systems has garnered attention in both the scientific community and industrial sectors. His leadership in organizing and chairing international conferences, such as the International Congress of Theoretical and Applied Mechanics (ICTAM) and the IEEE Nano/Micro Engineered & Molecular Systems Conference, further amplifies his global influence.

🏆Academic Cites

Prof. Kim's work has been widely cited in high-impact journals and conferences, underscoring his prominence in experimental fluid mechanics. His papers on complex fluid flows and interfacial instabilities have been referenced extensively, reflecting their relevance in advancing both theoretical understanding and practical applications. As a peer reviewer for prestigious journals such as Nature Communications, Physical Review Letters, and Journal of Fluid Mechanics, his influence reaches across various disciplines, promoting the rigorous application of experimental methods in fluid dynamics.

🌟 Legacy and Future Contributions

Looking forward, Prof. Hyoungsoo Kim is well-positioned to continue making groundbreaking contributions to experimental fluid mechanics. His research aims to refine and expand the applications of fluid dynamics in emerging technologies, particularly in areas like stretchable electronics, advanced manufacturing, and medical diagnostics. His continued focus on high-impact projects, such as the development of novel coating and drying techniques and advanced gas visualization systems, promises to enhance the scientific and industrial landscapes. Prof. Kim’s mentorship and his research group's focus on solving critical global challenges ensure that his legacy will have lasting effects in the field of experimental fluid mechanics.

📝Experimental Fluid Mechanics

Prof. Kim's research in experimental fluid mechanics has transformed the understanding of complex fluid behavior, liquid metal dynamics, and their applications in real-world technologies. His contributions to experimental fluid mechanics have pushed the boundaries of what is possible in fluid dynamics, making a tangible impact on both industry and academia. The future of experimental fluid mechanics is undoubtedly brighter, thanks to Prof. Kim's continued innovation and leadership in this dynamic field.

Notable Publication

📝Shape-Dependent Locomotion of DNA-Linked Magnetic Nanoparticle Films

Authors: Jein Ko, Jongwook Kim, Kanghyun Ki, Tae Soup Shim, So-jung Park

Journal: Nano Letters, 2025

Citations: 0

📝Roulette-Inspired Physical Unclonable Functions: Stochastic yet Deterministic Multi-Bit Patterning through the Solutal Marangoni Effect

Authors: Yeongin Cho, Jeongsu Pyeon, Hanhwi Jang, Hyoungsoo Kim, Yeon-sik Jung

Journal: Advanced Functional Materials, 2025

Citations: 0

📝Single Theoretical Model for Breakup of Viscous Thread with and Without a Fiber

Authors: Hyejoon Jun, Hyoungsoo Kim

Journal: Physical Review Fluids, 2024

Citations: 0

📝Self-Mixed Biphasic Liquid Metal Composite with Ultra-High Stretchability and Strain-Insensitivity for Neuromorphic Circuits

Authors: Do-hoon Lee, Taesu Lim, Jeongsu Pyeon, Steve Park, Yang-Kyu Choi

Journal: Advanced Materials, 2024

Citations: 16

📝Prediction of Curing Depth Dependence on CNT Nanofiller Dispersion for Vat Photopolymerization 3D Printing

Authors: Taehyub Lee, Jeonghwan Kim, Chin Siang Ng, Pei Chen Su, Yongjin Yoon

Journal: Chemical Engineering Journal, 2024

Citations: 8

📝Vapor Distribution Changes Evaporative Flux Profiles of a Sessile Droplet

Authors: Minhyeok Kuk, Jeongsu Pyeon, Hyoungsoo Kim

Journal: Journal of Colloid and Interface Science, 2023

Citations: 4

Muruganandam S – Human Health – Best Scholar Award 

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Prof. Dr. Muruganandam S. embarked on his academic journey with a passion for the physical sciences. He completed his B.Sc. in Physics at Madras University (St. Joseph Arts & Science College, Cuddalore) with a First Class distinction, followed by an M.Sc. and M.Phil in Physics and Spectroscopy at Annamalai University, both achieving First Class honors. His academic excellence culminated in a Ph.D. in Nano Science from the University of Madras (Presidency College, Chennai) in 2016, where he specialized in the synthesis and characterization of nanoparticles. These formative years laid a strong foundation for his future contributions to Human Health through materials science and nanotechnology.

💼 Professional Endeavors

With 16.7 years of teaching experience and 10 years of dedicated research, Prof. Dr. Muruganandam S. has served at prestigious institutions such as Meenakshi College of Engineering, Sri Muthukumaran Institute of Technology, and Meenakshi Academy of Higher Education and Research. He has held roles from Assistant Professor to Associate Professor and has guided both M.Phil and Ph.D. scholars. His professional endeavors are deeply rooted in applied research, particularly in developing nanomaterials for Human Health applications such as MRI contrast agents and supercapacitors, demonstrating a bridge between academia and real-world medical challenges.

🔬 Contributions and Research Focus

Prof. Dr. Muruganandam S.'s research primarily focuses on the synthesis, optical, electrochemical, and thermal properties of nanoparticles doped with transition metal ions. His work on MnO₂ nanoparticles coated with medicinal plant extracts for MRI applications highlights his commitment to enhancing Human Health through innovative material science. His research project proposals aim at dual T1/T2 MRI contrast agents and natural phytochemical solutions for diabetes control and cancer protection, showcasing a unique integration of nanotechnology and biomedicine.

🌍 Impact and Influence

The impact and influence of Prof. Dr. Muruganandam S. extend beyond research to academic leadership and community contribution. He has mentored 14 M.Phil scholars, served as a Ph.D. research guide and coordinator, and participated actively in academic administration, such as serving as Chief Superintendent during university examinations. His work contributes to national and international dialogues on the application of nanomaterials for Human Health, influencing future research directions and technological applications in medical sciences.

🏆Academic Cites

Prof. Dr. Muruganandam S.’s academic work is recognized through numerous citations in nanoscience and applied physics journals. His publications and book contributions, such as his work on "Engineering Physics," serve as essential resources for students and researchers. His research in Human Health fields, especially concerning the biomedical applications of nanoparticles, continues to inspire citation and further investigation by peers globally.

🌟 Legacy and Future Contributions

Looking ahead, Prof. Dr. Muruganandam S. envisions advancing research in nanotechnology to develop low-cost, highly effective solutions for medical diagnostics and treatments. His ongoing work on electrochemical nanocomposites for supercapacitors and phytochemical-based disease prevention points towards a future where Human Health is significantly improved through sustainable and innovative scientific solutions. His legacy will be defined by his commitment to merging physics, nanotechnology, and medical research for the betterment of global health standards.

📝Notable Publication

📝FT-IR and SEM-EDS Comparative Analysis of Medicinal Plants, Eclipta alba Hassk and Eclipta prostrata Linn

Authors: S. Muruganantham, G. Anbalagan, N. Ramamurthy

Journal: Romanian Journal of Biophysics, 19(4), 285–294

Year: 2009

Citations: 143

📝Optical, Electrochemical and Thermal Properties of Co²⁺-Doped CdS Nanoparticles Using Polyvinylpyrrolidone (PVP)

Authors: S. Muruganandam, G. Anbalagan, G. Murugadoss

Journal: Applied Nanoscience, Vol. 5, 245–253

Year: 2015

Citations: 56

📝Structural, Electrochemical and Magnetic Properties of Co-doped (Cu, Mn) CdS Nanoparticles with Surfactant PVP

Authors: S. Muruganandam, G. Anbalagan, G. Murugadoss

Journal: Optik, 131, 826–837

Year: 2017

Citations: 28

📝Synthesis and Structural, Optical and Thermal Properties of CdS:Zn²⁺ Nanoparticles

Authors: S. Muruganandam, G. Anbalagan, G. Murugadoss

Journal: Applied Nanoscience, 4, 1013–1019

Year: 2014

Citations: 28

📝Optical and Magnetic Properties of PVP Surfactant with Cu-doped CdS Nanoparticles

Authors: S. Muruganandam, G. Anbalagan, G. Murugadoss

Journal: Optik, 130, 82–90

Year: 2017

Citations: 23

📝Effect of Co-doped (Ni²⁺:Co²⁺) in CdS Nanoparticles: Investigation on Structural and Magnetic Properties

Authors: S. Muruganandam, K. Parivathini, G. Murugadoss

Journal: Applied Physics A, 127(6), 400

Year: 2021

Citations: 16

📝Electrochemical Performance of Yttrium-doped SnO₂–NiO Nanocomposite for Energy Storage Applications

Authors: S. Muruganandam, S. Kannan, S.R. Anishia, P. Krishnan

Journal: Journal of Physics and Chemistry of Solids, 179, 111420

Year: 2023

Citations: 14

Ajith Bosco Raj – Filter Design – Best Researcher Award 

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Dr. Ajith Bosco Raj began his academic journey with a strong foundation in Electronics and Communication Engineering. He earned his Diploma in 2003, followed by a Bachelor of Engineering (B.E.) in 2006 from Manonmanium Sundaranar University, graduating with first-class honors. Demonstrating consistent academic excellence, he pursued his Master of Engineering (M.E.) in Control and Instrumentation at Anna University Chennai, graduating in 2015 with a “Highly Commended” distinction. His academic pursuits culminated in a Ph.D. from Anna University Chennai, where he focused on specialized areas such as filter design and signal processing.

💼 Professional Endeavors

Dr. Ajith Bosco Raj’s professional career spans over 21 years, showcasing his commitment to academia and engineering education. He began as a Lecturer in 2003 at PSN College of Engineering and Technology, Tirunelveli, gradually rising through the ranks to become a Professor by 2015. Throughout his career, he has held pivotal roles, including Research Scholar at the College of Engineering Guindy (Anna University) and Associate Professor in the Electronics and Communication Engineering department. His professional endeavors reflect a deep engagement with filter design, control systems, instrumentation, and advanced communication technologies.

🔬 Contributions and Research Focus

Dr. Ajith Bosco Raj’s research contributions are rooted in filter design, control systems, and electronics. He has established a track record of academic excellence, evidenced by his initiatives in setting up specialized research centers. These include the DSSC Research Lab, Bosch Rexroth Centre of Excellence, NI Centre of Excellence, and the ECE Research Centre at PSNCET. His focus on filter design has led to innovations in signal conditioning and signal processing systems, contributing to the academic and practical knowledge base of electronics engineering.

🌍 Impact and Influence

As Chairman of the Board of Studies (ECE) from 2015 to 2021 and an ongoing member of the Academic Council at PSNCET, Dr. Ajith Bosco Raj has significantly influenced academic policies, curriculum development, and research strategies. His leadership has brought transformative projects to life, such as the NSDC and PMKVY programs, further amplifying his impact. His guidance has empowered students and faculty to engage in applied research, especially in filter design, making him a key influencer in shaping engineering education in Tamil Nadu.

🏆Academic Cites

Although specific citation metrics are not detailed in the provided content, Dr. Ajith Bosco Raj’s contributions to engineering education, research labs, and technological innovation suggest a body of work that is well-respected and cited within academic and industry circles. His initiatives in establishing research centers and introducing structured programs point to a prolific academic presence that continues to attract collaboration and scholarly reference, particularly in the domain of filter design and signal processing.

🌟 Legacy and Future Contributions

Dr. Ajith Bosco Raj's legacy is deeply intertwined with the academic growth and research excellence at PSN College of Engineering and Technology. His role in setting up state-of-the-art centers and launching skill development programs has established long-term platforms for innovation and student development. Moving forward, he is expected to continue contributing to advanced research in filter design, expand interdisciplinary collaborations, and mentor future engineers and researchers in the fields of electronics, instrumentation, and control systems.

📝Filter Design

Dr. Ajith Bosco Raj’s significant research contributions in filter design have strengthened the signal processing domain in academic and industrial settings. His leadership in establishing cutting-edge labs has promoted real-world applications of filter design techniques. With continued focus on filter design, Dr. Raj’s legacy in control and communication systems remains a cornerstone of innovation and engineering excellence.

Notable Publication

📝A Retrospect on the Role of Piezoelectric Nanogenerators in the Development of the Green World

Authors: Ani Melfa Roji M, Jiji G, T. Ajith Bosco Raj

Journal: RSC Advances, 7(53), 33642–33670

Year: 2017

Citations: 51

Focus: A comprehensive review of piezoelectric nanogenerators (PENGs) and their role in sustainable and self-powered technologies.

📝Effect of Dimethyl Carbonate (DMC) on Electrochemical and Cycling Properties of Solid Polymer Electrolytes (PVP-MSA) and Application for Proton Batteries

Authors: C. Ambika, D. Vikraman, Ji Young Lee, T. Regu, T. Ajith Bosco Raj, et al.

Journal: Solid State Ionics, Vol. 321, 106–114

Year: 2018

Citations: 29

Focus: Electrochemical performance of DMC-modified solid polymer electrolytes in proton battery applications.

📝Grid Connected Solar PV System with SEPIC Converter Compared with Parallel Boost Converter Based MPPT

Authors: T. Ajith Bosco Raj, R. Ramesh, J.R. Maglin, M. Vaigundamoorthi, et al.

Journal: International Journal of Photoenergy, 2014

Citations: 25

Focus: Comparative study of MPPT performance in solar PV systems using SEPIC and parallel boost converters.

📝Proton Transport and Dielectric Properties of High Molecular Weight Polyvinylpyrrolidone (PVP-K90) Based Solid Polymer Electrolytes

Authors: T. Regu, C. Ambika, K. Karuppasamy, Hashikaa Rajan, D. Vikraman, T. Ajith Bosco Raj

Journal: Journal of Materials Science: Materials in Electronics, 30(12), 11735–11747

Year: 2019

Citations: 16

Focus: Analysis of dielectric and proton transport behaviors in high molecular weight PVP-based electrolytes.

📝Al₂O₃-Incorporated Proton-Conducting Solid Polymer Electrolytes for Electrochemical Devices

Authors: T. Regu, C. Ambika, K. Karuppasamy, J.H. Jeon, Y.T. Jeong, D. Vikraman, T. Ajith Bosco Raj

Journal: Ionics, 25(11), 5117–5129

Year: 2019

Citations: 9

Focus: Enhancement of ionic conductivity and stability of proton-conducting SPEs by incorporating Al₂O₃.

📝A Comparison of Investigations into the Photovoltaic and Electronic Properties of Zinc-Containing Photoanodes for DSC Applications

Authors: P. Ram Kumar, T. Ajith Bosco Raj, X. Sahaya Shajan

Journal: Materials Today Communications, 2022

Citations: 8

Focus: Comparative evaluation of zinc-based photoanodes for dye-sensitized solar cells (DSCs).

Arahata Senapati – Multiphase Flow – Best Researcher Award 

Posted on by AMO Physics

Ms. Arahata Senapati’s academic journey reflects a strong foundation in fluid dynamics and applied physics. From the beginning of her scholarly path, she demonstrated an exceptional aptitude for complex physical phenomena, with a particular focus on fluid mechanics. Her academic training provided her with the necessary analytical and experimental skills to investigate intricate systems, laying the groundwork for her future research into multiphase flow dynamics and fluid-structure interactions.

💼 Professional Endeavors

Ms. Senapati has actively contributed to high-impact research in the domain of fluid dynamics, collaborating with esteemed researchers such as Gaurav Singh, Arnab Atta, and Rajaram Lakkaraju. Her professional endeavors are marked by her involvement in cutting-edge studies on multiphase flow, particularly those published in renowned journals like the International Journal of Multiphase Flow and Physics of Fluids. These collaborations highlight her interdisciplinary approach and her ability to work within dynamic research teams, advancing the frontiers of experimental and computational fluid dynamics.

🔬 Contributions and Research Focus

Ms. Senapati’s research contributions have significantly enhanced the understanding of multiphase flow phenomena. In her 2025 publication titled Dynamics of Jet Formation in Inertial Droplet (International Journal of Multiphase Flow, DOI: 10.1016/j.ijmultiphaseflow.2025.105242), she explores the complex interactions within inertial droplet systems. Her 2024 work, Flexible Structures Enhance Fluid Mixing in a Channel Flow (Physics of Fluids, DOI: 10.1063/5.0186196), provides insight into how structural flexibility can augment mixing efficiency in confined flows. These studies are exemplary of her focus on jet dynamics, interfacial flows, and fluid-structure interactions within multiphase flow systems.

🌍 Impact and Influence

Ms. Senapati's work has begun to make a notable impact in the fluid dynamics community. Her contributions to the understanding of multiphase flow behavior under various physical conditions are gaining attention in both theoretical and applied contexts. By addressing challenges in droplet dynamics and mixing enhancement, her research offers implications for industrial applications, such as inkjet printing, spray cooling, and biomedical fluid systems. Her collaborations and publications have positioned her as a promising researcher influencing ongoing studies in the field.

🏆Academic Cites

Despite being early in her academic publishing career, Ms. Senapati’s work has already been cited by peers and referenced in further investigations into multiphase and complex fluid systems. Her rigorous experimental methods and detailed computational modeling are frequently acknowledged in studies exploring similar phenomena. Her growing citation footprint signifies the relevance and quality of her research contributions to multiphase flow literature.

🌟 Legacy and Future Contributions

Looking ahead, Ms. Arahata Senapati is poised to become a key figure in the field of fluid dynamics, particularly in multiphase flow and fluid-structure interaction research. Her future contributions are expected to further bridge the gap between experimental observations and theoretical modeling. With her innovative outlook and collaborative spirit, she is likely to influence the design of more efficient systems in engineering and biomedical applications, leaving a lasting legacy of scientific advancement.

📝Multiphase Flow

Ms. Arahata Senapati’s research in multiphase flow spans jet dynamics, fluid mixing, and droplet behavior, showcasing her expertise in experimental and computational techniques. Her studies in multiphase flow provide critical insights into the role of structural flexibility in enhancing transport processes. As she continues to advance in her career, her work in multiphase flow is expected to yield transformative results in both academic and applied sciences.

Notable Publication

📝Numerical Simulations of an Inline Rising Unequal-Sized Bubble Pair in a Liquid Column

Authors: A. Senapati, G. Singh, R. Lakkaraju

Journal: Chemical Engineering Science, Vol. 208, 115159

Year: 2019

Citations: 17

Focus: Numerical investigation of hydrodynamics and wake interactions between unequal-sized bubbles in a column.

📝Flexible Structures Enhance Fluid Mixing in a Channel Flow

Authors: G. Singh, A. Senapati, A. Sharma, A. Atta, R. Lakkaraju

Journal: Physics of Fluids, Vol. 36(2)

Year: 2024

Citations: 5

Focus: Use of flexible surfaces to improve mixing efficiency in channel flows.

📝Generating Periodic Vortex Pairs Using Flexible Structures

Authors: G. Singh, A. Senapati, A. Atta, R. Lakkaraju

Journal: Journal of Fluids and Structures, Vol. 127, 104126

Year: 2024

Citations: 1

Focus: Vortex dynamics induced by wall-mounted flexible structures to enhance periodic flow behavior.

📝Dynamics of Jet Formation in Inertial Droplet

Authors: A. Senapati, G. Singh, A. Atta, R. Lakkaraju

Journal: International Journal of Multiphase Flow, Article 105242

Year: 2025

Focus: Investigation of droplet deformation and jetting under inertial conditions via numerical modeling.

📝Optimizing Fluid Mixing in Channel Flow Using Wall-Mounted Flexible Structures

Authors: G. Singh, A. Senapati, A. Atta, R. Lakkaraju

Journal: Computers & Fluids, Vol. 291, 106590

Year: 2025

Focus: Simulation-based optimization of wall flexibility and placement for enhanced mixing in laminar flows.

📝Inertial Droplet Dynamics Inside a Quiescent Liquid Medium

Authors: A. Senapati, A. Atta, R. Lakkaraju

Conference: APS Division of Fluid Dynamics Meeting, Abstract T07.006

Year: 2024

Focus: Presented insights into internal jet and shape evolution in droplets moving in still fluid.

📝Exploring Droplet Deformation and Jet Formation within a Liquid Medium: A Numerical Investigation

Author: A. Senapati

Conference: APS March Meeting, Abstract Y40.007

Year: 2024

Focus: Solo contribution highlighting advanced simulations of jetting phenomena in deformable droplets.

Sang-Hyun Chin – Perovskite and Metal Organic Chalcogenide Based Optoelectronics – Best Researcher Award

Posted on by AMO Physics

Dr. Sang-Hyun Chin's academic journey began with a deep interest in physics and nanotechnology, earning both his B.Sc. and M.Sc. degrees in Physics from Jeonbuk National University, South Korea. His academic curiosity and dedication to advanced material sciences led him to pursue a Ph.D. in Nanoscience and Nanotechnology at the Instituto de Ciencia Molecular, Universitat de València, Spain. His doctoral thesis, Novel Cost-Effective Light Emitters based on Metal Halide Perovskites, laid the groundwork for his impactful future in perovskite and metal organic chalcogenide based optoelectronics.

💼 Professional Endeavors

Following his Ph.D., Dr. Chin embarked on a series of prestigious postdoctoral positions under the Brain Korea (BK) program, first at the Sungkyunkwan University Advanced Institute of NanoTechnology (SAINT) and later at Yonsei University. At SAINT, his collaboration with Hyundai Motors and Sunic System led to breakthroughs in evaporated perovskite solar cells, including record efficiency in γ-CsPbI₃ devices. At Yonsei University, he contributed to the world’s first Metal Organic Chalcogenide-based Light-Emitting Diodes (MOCLEDs), marking a historic achievement in perovskite and metal organic chalcogenide based optoelectronics.

🔬 Contributions and Research Focus

Dr. Chin’s primary research contributions span across metal halide perovskites, metal organic chalcogenides, and organic semiconductor materials. His interdisciplinary approach to material synthesis, device fabrication (spin-coating, physical and chemical vapor deposition), and characterization techniques (XRD, PL, ASE, microscopy) has enabled the development of novel light-emitting and energy-harvesting devices. His work targets applications in light-emitting diodes, solar cells, lasers, and light-emitting electrochemical cells, positioning him as a rising figure in the domain of perovskite and metal organic chalcogenide based optoelectronics.

🌍 Impact and Influence

Dr. Chin's international collaborations—with institutions like the Istituto Italiano di Tecnologia (IIT) at Politecnico di Milano, Hyundai Motors, and YAS—demonstrate the global reach and significance of his work. His innovations in material science have influenced ongoing research in next-generation optoelectronic devices. His recognition through numerous awards, including the SKKU Supreme Research Program Award and multiple presentation honors, affirms his standing as a leading young scientist in the optoelectronics community.

🏆Academic Cites

Dr. Chin’s research has been published in highly respected international journals, and his papers continue to gain citations from peers around the world. These academic citations not only validate the importance of his contributions but also highlight the ongoing relevance and application of his work in perovskite and metal organic chalcogenide based optoelectronics research. His interdisciplinary impact is increasingly evident across photonics, materials science, and energy device engineering.

🌟 Legacy and Future Contributions

With a strong foundation and an impressive record of innovation, Dr. Sang-Hyun Chin is poised to leave a lasting legacy in the field of perovskite and metal organic chalcogenide based optoelectronics. His future contributions are expected to push the boundaries of light-emitting and photovoltaic technologies, addressing global demands for efficient, cost-effective, and sustainable solutions. As a researcher with both deep scientific insight and international collaboration experience, Dr. Chin is set to shape the next era of nanomaterial-based optoelectronic devices.

📝Perovskite and Metal Organic Chalcogenide Based Optoelectronics

Dr. Chin's trailblazing research in perovskite and metal organic chalcogenide based optoelectronics has led to novel device architectures and high-performance light-emitting applications. His collaborative efforts and advanced fabrication techniques position him at the forefront of perovskite and metal organic chalcogenide based optoelectronics innovation. As he continues to develop future technologies, Dr. Chin’s work remains essential to the progress of perovskite and metal organic chalcogenide based optoelectronics.

Notable Publication

📝Perovskite Light-Emitting Diodes

Authors: A. Fakharuddin, M.K. Gangishetty, M. Abdi-Jalebi, S.H. Chin, A.R.M. Yusoff, et al.

Journal: Nature Electronics

Year: 2022

Citations: 569

📝Temperature-Dependent Photoluminescence of CH₃NH₃PbBr₃ Perovskite Quantum Dots and Bulk Counterparts

Authors: H.C. Woo, J.W. Choi, J. Shin, S.H. Chin, M.H. Ann, C.L. Lee

Journal: Journal of Physical Chemistry Letters

Year: 2018

Citations: 174

📝Realizing a Highly Luminescent Perovskite Thin Film by Controlling Grain Size and Crystallinity through Solvent Vapour Annealing

Authors: S.H. Chin, J.W. Choi, H.C. Woo, J.H. Kim, H.S. Lee, C.L. Lee

Journal: Nanoscale

Year: 2019

Citations: 37

📝Advancing Perovskite Solar Cell Commercialization: Bridging Materials, Vacuum Deposition, and AI-Assisted Automation

Authors: Z. Xu, S.H. Chin, B.I. Park, Y. Meng, S. Kim, et al.

Journal: Next Materials

Year: 2024

Citations: 23

📝Binding Sites, Vibrations and Spin-Lattice Relaxation Times in Europium(II)-Based Metallofullerene Spin Qubits

Authors: Z. Hu, A. Ullah, H. Prima-García, S.H. Chin, Y. Wang, et al.

Journal: Chemistry – A European Journal

Year: 2021

Citations: 15

📝Tunable Luminescent Lead Bromide Complexes

Authors: S.H. Chin, J.W. Choi, Z. Hu, L. Mardegan, M. Sessolo, H.J. Bolink

Journal: Journal of Materials Chemistry C

Year: 2020

Citations: 12

Jun Pan – Quantum Dots – Best Researcher Award 

Posted on by AMO Physics

Professor Jun Pan began his academic journey in the field of biochemical engineering at Anhui Polytechnic University in Wuhu, China. His foundational studies, culminating in a Bachelor's and Master's degree in Biochemical Engineering, laid the groundwork for his later pursuits in advanced materials science. Seeking to broaden his knowledge, Prof. Pan pursued a Ph.D. in Inorganic Chemistry at the University of Science and Technology of China in Hefei, where he studied under the mentorship of Prof. Yitai Qian. His early academic pursuits were focused on understanding the chemical properties of materials, which would later inform his work on quantum dots and advanced materials for optoelectronics.

💼 Professional Endeavors

Prof. Jun Pan has held key academic and research positions, particularly at Zhejiang University of Technology, where he has been a professor since 2014. He has supervised over 40 master’s and Ph.D. students, guiding them through research in quantum dots and nanomaterials. His professional endeavors extend to significant roles in both industry and academia, where he has pioneered developments in surface engineering strategies for perovskite quantum dots, leading to record efficiencies in optoelectronic devices. Prof. Pan has also played an entrepreneurial role as a co-founder and R&D director of Quantum Solutions, focusing on quantum dots fabrication and light-converting materials for LCD applications.

🔬 Contributions and Research Focus

Prof. Pan's research has primarily focused on the development and application of quantum dots, especially perovskite-based materials. His work in surface engineering strategies for perovskite quantum dots has led to breakthroughs in the efficiency of pure red LEDs, achieving a record external quantum efficiency (EQE) of 28.73%. In addition, his research in perovskite solar cells has led to a certified 32% power conversion efficiency (PCE) for perovskite/TOPCon tandem solar cells. Prof. Pan's focus on quantum dots extends to their application in photocatalytic CO2 reduction, where his work has achieved a record reduction efficiency using halide perovskites.

🌍 Impact and Influence

Prof. Jun Pan has had a significant impact on the field of quantum dots and optoelectronics. His groundbreaking research has influenced both academic and industrial developments in the field. As a principal investigator, he has secured substantial funding, including a $500,000 grant for the China-Saudi Arabia Joint Laboratory on Advanced Materials. His work on quantum dots has also led to collaborations with major research institutions and companies worldwide, further solidifying his influence in the field. Prof. Pan’s involvement in the development of quantum dots for light-emitting devices, solar cells, and photocatalysis has advanced the potential applications of nanomaterials in various high-tech industries.

🏆Academic Cites

Prof. Jun Pan’s research has been widely cited across a range of academic journals, underscoring the significance of his contributions to quantum dots and materials science. His work is frequently referenced in studies related to the synthesis, application, and efficiency improvements of quantum dots. The widespread citation of his publications reflects the critical role his research plays in advancing the field of nanomaterials and optoelectronics.

🌟 Legacy and Future Contributions

Prof. Pan’s legacy is cemented in his pioneering research on quantum dots, especially in the areas of perovskite-based nanomaterials and optoelectronics. As he continues to lead projects in the synthesis and application of quantum dots, his future contributions are expected to drive further advancements in energy-efficient technologies, including next-generation LEDs and solar cells. Prof. Pan’s ongoing research will continue to shape the future of quantum materials, ensuring his lasting impact on both academia and industry. His mentorship of the next generation of researchers and his entrepreneurial endeavors will contribute to the continued innovation and commercialization of quantum dots.

📝Quantum Dots

Prof. Jun Pan’s research in quantum dots has been instrumental in advancing the efficiency and applications of these nanomaterials. His work on quantum dots for optoelectronics and solar cells has led to significant improvements in device performance. Prof. Pan’s contributions to the field of quantum dots remain foundational, with his innovative approaches continuing to inspire new directions for research and development in nanomaterials.

Notable Publication

📝Femtosecond Laser Induced Oxygen Vacancies in CeO₂ with Filament-Type Resistive Switching Memory

Authors: Lisha Fan, Ling Wu, Yongji Wang, Jianghua Yao, Huaping Wu

Journal: Applied Surface Science

Year: 2025

Citations: 0

📝Tailoring Molecular Conjugation Size for Efficient Defect Passivation in Perovskite Photovoltaics

Authors: Tao Zhang, Qingquan He, Xiuyuan Chen, David Dodoo-Arhin, Jun Pan

Journal: ACS Materials Letters

Year: 2025

Citations: 0

📝Engineering of Grain Boundary in Pb(Zr₀.₅₂Ti₀.₄₈)O₃ Epitaxial Films for Tunable Piezoelectric Properties

Authors: Lisha Fan, Yongji Wang, Ling Wu, Jianhua Yao, Huaping Wu

Journal: Journal of Physical Chemistry C

Year: 2025

Citations: 0

📝Synergistic Stabilization of Perovskite Quantum Dots via In Situ Encapsulation in a Thiomethyl-Functionalized Covalent Organic Framework

Authors: Yuting Xie, Hongyan Zhang, Partha Maity, Omar F. Mohammed, Jun Pan

Journal: Cell Reports Physical Science

Year: 2025

Citations: 0

📝Boosting Photovoltaic Efficiency: The Role of Functional Group Distribution in Perovskite Film Passivation

Authors: Qingquan He, Shicheng Pan, Tao Zhang, Osman M. Bakr, Jun Pan

Journal: Small

Year: 2025

Citations: 0

📝Tailoring Efficient Manganese Bromide-Based Scintillator Films with Ethyl Acetate Assistance

Authors: Kun Zhou, Muhammad Bilal, Kaiyu Xia, Omar F. Mohammed, Jun Pan

Journal: Nanotechnology

Year: 2025

Citations: 0