Minseong Ko | Energy | Best Researcher Award

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Prof. Minseong Ko | Energy | Best Researcher Award

Pukyong National University | South Korea

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🌟 Early Academic Pursuits

Prof. Minseong Ko's journey into the world of materials science and battery technology began with a strong academic foundation. He obtained his Bachelor of Science degree from Pukyong National University in the Department of Materials Science and Engineering. His passion for advanced materials led him to pursue a Master’s degree at Gwangju Institute of Science & Technology (GIST), where he focused on enhancing the sensitivity of GMR Spin Valve Sensors. He continued his academic excellence by earning a Ph.D. in Battery Science & Technology from the Ulsan National Institute of Science & Technology (UNIST). Under the guidance of esteemed mentors, including Prof. Jaephil Cho, he gained deep insights into lithium-ion batteries (LIBs) and energy storage technologies. His academic journey culminated in postdoctoral research at the Massachusetts Institute of Technology (MIT), where he worked under the mentorship of Prof. Ju Li, further strengthening his expertise in nuclear science and engineering.

💼 Professional Endeavors

Currently, Prof. Minseong Ko serves as an Associate Professor in the Department of Metallurgical Engineering at Pukyong National University, Busan, Republic of Korea. His professional trajectory has been marked by his contributions to battery technology and materials science. Throughout his career, he has engaged in cutting-edge research, focusing on the synthesis and functionalization of carbon materials, modification of nanomaterials, and the development of coating equipment for mass production. His role as an educator is equally significant, having taught and mentored students in advanced energy storage materials at prestigious institutions such as UNIST and Pukyong National University.

📈 Contributions and Research Focus

Prof. Ko’s research primarily revolves around all-solid-state batteries and lithium-ion battery (LIB) materials. His pioneering work in synthesizing cathode and anode materials aims to enhance energy storage efficiency, improve fast-charging capabilities, and ensure the non-flammability of LIBs. His expertise extends to in-situ analysis of electrode materials and HPPC (Hybrid Pulse Power Characterization) testing for electric vehicles. Additionally, he has been instrumental in the development of large-scale synthesizing equipment for commercialization, bridging the gap between academic research and industrial application.

His research interests include:

  • Development of high-energy and fast-charging lithium-ion batteries
  • Synthesis and surface modification of electrode materials
  • Fabrication of electrochemical full-cells (pouch and coin-type)
  • Commercialization and mass production of battery materials

🏆 Accolades and Recognition

Prof. Ko’s contributions to battery science have been widely recognized in the academic and industrial sectors. His groundbreaking research has been published in top-tier journals, including Nature Communications, Advanced Energy Materials, ACS Nano, and Nano Letters. These publications highlight his significant contributions to the advancement of high-performance lithium-ion batteries and nanomaterial applications. His work has not only earned him academic accolades but has also positioned him as a leader in the field of energy storage technology.

🔋 Impact and Influence

Through his extensive research and publications, Prof. Ko has made a lasting impact on the field of energy storage. His studies on silicon-based anodes and high-capacity cathode materials have paved the way for more efficient and durable lithium-ion batteries, crucial for applications in electric vehicles and renewable energy systems. His collaborative approach has also contributed to global advancements in materials engineering, fostering partnerships between academia and industry to drive innovation. Beyond research, Prof. Ko is deeply committed to mentoring the next generation of scientists and engineers. His teaching philosophy emphasizes hands-on experimentation and industry collaboration, equipping students with the skills needed to tackle real-world challenges in battery technology.

🌍 Legacy and Future Contributions

Looking ahead, Prof. Minseong Ko aims to further revolutionize battery technology by developing next-generation solid-state batteries with enhanced safety and performance. His research endeavors continue to focus on improving the longevity, efficiency, and sustainability of energy storage systems. As a respected scientist and mentor, he is set to leave a lasting legacy in the fields of materials science and electrochemical energy storage. With his unwavering dedication to innovation and excellence, Prof. Ko’s contributions will undoubtedly shape the future of sustainable energy solutions, benefiting industries and societies worldwide.

 

Publications

📄 "Morphology Control of Al Oxide Coating to Suppress Interfacial Degradation in Ultra-high Nickel Cathode Materials"

  • Authors: Minseong Kim, Jiyun Park, Taewan Kim, Byeonggu Kang, Jaegeon Im, Minseong Ko, Sujong Chae

  • Journal: Electrochimica Acta

  • Year: 2025

📄 "Binder-free CNT-implanted Carbon Cloth and Carbon Felt as Cathode Modifier for Bioelectricity Generation in Sediment Microbial Fuel Cells"

  • Authors: Nurfarhana Nabila Mohd Noor, Rashida Misali, Minseong Kim, Jeongmok Park, Minseong Ko, In-Cheol Lee, Tadashi Hibino, Kyunghoi Kim

  • Journal: Journal of the Taiwan Institute of Chemical Engineers

  • Year: 2025

 

Shengyang Dong | Materials Science | Best Researcher Award

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Prof. Shengyang Dong | Materials Science | Best Researcher Award

Nanjing University of Information Science and Technology | China

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Early Academic Pursuits 📚

Prof. Shengyang Dong embarked on his academic journey at Nanjing University of Aeronautics and Astronautics, where he earned his Doctor of Engineering degree in June 2019. During his Ph.D., he had the invaluable opportunity to study as an exchange scholar at Oregon State University under the guidance of Prof. Xiulei Ji (2016–2017). This exposure enriched his expertise and broadened his research horizons. He later joined Nanjing University of Information Science and Technology, marking the start of an illustrious academic career. Prof. Dong’s academic roots laid the foundation for his groundbreaking work in sustainable energy storage and conversion systems.

Professional Endeavors 🏛️

After joining Nanjing University of Information Science and Technology, Prof. Dong dedicated himself to advancing research in energy storage. As a Macao Young Scholar (2023–2025), he expanded his professional experience at the University of Macau. His efforts have resulted in the successful completion of seven research projects and the publication of 61 SCI papers, garnering over 5,300 citations. Prof. Dong has also made significant contributions through consultancy projects, editorial roles, and collaborations with renowned researchers worldwide. His professional journey reflects a blend of academic rigor and innovative vision.

Contributions and Research Focus 🔬

Prof. Dong’s research primarily targets sustainable energy storage and conversion technologies, focusing on aqueous batteries, Na-ion batteries, and dual-ion batteries. He pioneered studies on the electrode–charge carrier ion interaction, revealing its profound impact on electrochemical performance. By exploring the role of chemical bonding, such as hydrogen bonds in NH4+ and metal oxide systems, he introduced novel factors influencing battery design. These findings have paved new paths for optimizing electrode and charge carrier interactions, offering a transformative approach to energy storage device development.

Accolades and Recognition 🏆

Prof. Dong's achievements have earned him recognition in academic and professional circles. He holds nine patents and has contributed chapters to two notable books, enhancing the understanding of energy storage systems. He serves on the editorial boards of leading journals like Materials Research Letters and Rare Metals. His contributions to the field are widely acknowledged, with collaborators spanning institutions such as Zhejiang University, Nanjing Tech University, and the City University of Hong Kong. Prof. Dong’s work continues to inspire innovation and collaboration in energy storage research.

Impact and Influence 🌍

The impact of Prof. Dong’s research extends beyond academic publications. His insights into electrode–ion interactions have reshaped the design principles for electrochemical storage devices, influencing both theoretical studies and practical applications. By addressing challenges in sustainability and performance, his work contributes significantly to global efforts in developing efficient energy storage solutions. His patents and consultancy projects underscore the translational impact of his research, bridging the gap between academia and industry.

Legacy and Future Contributions 🔮

As an academic leader, Prof. Dong’s legacy lies in his transformative contributions to sustainable energy technologies. His dedication to mentoring the next generation of scientists, collaborating with global experts, and exploring innovative research avenues ensures a lasting impact. Looking ahead, his work promises to drive advancements in energy storage solutions, aligning with the world’s transition to renewable energy systems. With a robust foundation and a visionary approach, Prof. Dong is poised to leave an enduring mark on the field of energy storage and beyond.

 

Publications

📄Fast synthesis of high-entropy oxides for lithium-ion storage
Author(s): Ren, R., Xiong, Y., Xu, Z., Yin, K., Dong, S.
Journal: Chemical Engineering Journal
Year: 2024

📄Ru-induced lattice expansion of metallic Co with favorable surface property for high-efficiency water electrolysis
Author(s): Shen, J., Zhang, M., Huang, Y., Wang, S., Shao, H.
Journal: Applied Catalysis B: Environmental
Year: 2024

📄Aqueous “rocking-chair” Mn-ion battery based on an industrial pigment anode
Author(s): Dong, S., Xu, Z., Cao, Z., Li, J., Dong, X.
Journal: Chemical Engineering Journal
Year: 2024

📄Synthesis of spinel (Mg₀.₂Co₀.₂Ni₀.₂Cu₀.₂Zn₀.₂)Fe₂O₄ in seconds for lithium-ion battery anodes
Author(s): Ren, R., Wu, D., Zhang, J., Zhang, Y., Dong, S.
Journal: Journal of Materials Chemistry A
Year: 2024

📄3D Printing of MXene-Enhanced Ferroelectric Polymer for Ultrastable Zinc Anodes
Author(s): Zhu, G., Zhang, H., Lu, J., Pang, H., Zhang, Y.
Journal: Advanced Functional Materials
Year: 2024

 

Shehzad Ahmed | Materials Science | Best Researcher Award

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Dr. Shehzad Ahmed | Materials Science | Best Researcher Award

Shenzhen University | China

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Early Academic Pursuits 🎓

Dr. Shehzad Ahmed's academic journey began with a Bachelor’s degree in Applied Physics from Kohat University of Science and Technology in Pakistan, where he researched thin film deposition techniques. This foundational interest propelled him toward a Master’s in Applied Physics at the International Islamic University in Islamabad, where he delved into the fascinating dynamics of magnetic nanoparticles. His early work here ignited his passion for materials science, especially in understanding complex material behaviors at the atomic level.

Professional Endeavors 🌍

Dr. Ahmed has held diverse roles, including Lecturer and Research Assistant at the International Islamic University, where he taught physics and developed expertise in nanotechnology research. He later served as an Assistant Professor at Sarhad University in Pakistan, delivering advanced courses in chemistry and supervising student research. His international experience includes a Visiting Fellowship at the Southern University of Science and Technology, Shenzhen, where he currently explores innovative materials for energy applications.

Contributions and Research Focus 🔬

Dr. Ahmed's primary research centers on the atomic structure and behavior of amorphous phase-change memory materials. He explores how structural disorder impacts the electrical, optical, and bonding properties of materials. His extensive work on Sb-Te phase-change memory materials aims to advance next-generation memory devices. Dr. Ahmed also investigates energy materials, batteries, catalysis, and nanotechnology, publishing numerous papers in top-tier scientific journals.

Accolades and Recognition 🏆

Dr. Ahmed's research achievements have been recognized through invitations to prestigious conferences, including the World Young Scientist Summit in Wenzhou and multiple Sino-German Bilateral Symposia on electronic and memory materials. His work has also earned him positions on international research collaborations, highlighting his impact within the global scientific community.

Impact and Influence 🌐

Dr. Ahmed's contributions to phase-change memory and amorphous materials science have paved the way for advancements in memory technology and sustainable energy solutions. His research is influential in guiding the design of high-performance materials, inspiring young scientists and students who look to his work as a foundation in materials science.

Legacy and Future Contributions 🌱

Dr. Ahmed envisions a career focused on pioneering discoveries in condensed matter physics and materials science, aiming to bridge academic research with industrial applications. His commitment to understanding and innovating materials for energy storage and catalysis positions him as a driving force for future advancements, ensuring a lasting legacy in the field of materials science.

 

Publications

  • 📄 "Polarization insensitive non-interleaved frequency multiplexed dual-band Terahertz coding metasurface for independent control of reflected waves"
    Authors: Iqbal, S., Noor, A., Ullah, N., Nisar, M.S., Wong, S.-W.
    Journal: Scientific Reports
    Year: 2024
  • 📄 "Enhanced As-COF nanochannels as a high-capacity anode for K and Ca-ion batteries"
    Authors: Ahmed, S., Ghani, A., Muhammad, I., Tian, X., Yakobson, B.
    Journal: Physical Chemistry Chemical Physics
    Year: 2024
  • 📄 "Revealing half-metallicity: Predicting large bandgaps in halogen-based full-Heusler alloys"
    Authors: Muhammad, I., Ahmed, S., Ullah, N., Tian, X., Zhang, J.-M.
    Journal: Results in Physics
    Year: 2024
  • 📄 "Unveiling the potential of aluminum-decorated 3D phosphorus graphdiyne as a catalyst for N₂O reduction"
    Authors: Ahmed, S., Khan, A.A., Khan, D., Xiaoqing, T., Muhammad, I.
    Journal: Physical Chemistry Chemical Physics
    Year: 2024
  • 📄"Giant Thermomechanical Bandgap Modulation in Quasi-2D Tellurium"
    Authors: Hussain, N., Ahmed, S., Tepe, H.U., Wu, H., Shcherbakov, M.R.
    Journal: Advanced Functional Materials
    Year: 2024

 

Byunghak Choe | Materials Science |Best Researcher Award

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Prof. Byunghak Choe | Materials Science |Best Researcher Award

Gangneung-Wonju National University  | South Korea 

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Early Academic Pursuits

Prof. Byunghak Choe began his distinguished academic journey at Seoul National University, Korea, where he earned his Bachelor of Science (1984), Master of Science (1986), and Ph.D. (1990) in Metallurgical Engineering. His early academic pursuits laid a solid foundation in metallurgy, focusing on the behavior of metal parts and their failure mechanisms.

Professional Endeavors

After completing his Ph.D., Prof. Choe joined the Korea Institute of Machinery and Metals (KIMM) as a Senior Researcher in the High-Temperature Materials Lab, where he worked from 1990 to 1995. In 1995, he transitioned to academia as a Professor in Advanced Metal & Materials Engineering. His tenure at Gangneung-Wonju National University has been marked by significant leadership roles, including serving as the Dean of the College of Engineering from 2018 to 2020. Additionally, he broadened his research horizons as a Visiting Scholar at Michigan Tech University, USA, from 2002 to 2003.

Contributions and Research Focus

Prof. Choe's research primarily revolves around failure analysis of metal parts and equipment. He has published more than ten research papers on this topic in the last eight years and has been involved in over ten projects in the last twelve years. His comprehensive work includes authoring multiple editions of "Failure Analysis for Metals," a key reference in the field. His recent research projects include technical reviews and failure analyses of turbine nozzle erosion, bellows specimens, heat-affected parts by fire for LNG tanks, and various other metal components. His notable publications delve into hydrogen-induced cracks in stainless steel, stress corrosion cracking propagation, and microstructural changes in cladding materials.

Accolades and Recognition

Prof. Choe's expertise in metallurgical engineering has earned him significant recognition. He serves as the Chairman of the KGS Code Committee at the Korea Gas Safety Corporation and has been the Vice President of Technology at the Korea Institute of Metals and Materials. His technical expertise is frequently sought after for accident investigations by the Korea Gas Safety Corporation and the Forensic Investigation Advisory Committee of the National Police Agency, Korea.

Impact and Influence

Prof. Choe's impact on the field of metallurgical engineering is profound. His research on failure analysis has advanced the understanding of how metals behave under stress and corrosive environments, particularly in high-temperature applications. His work on hydrogen embrittlement and stress corrosion cracking has provided valuable insights that have influenced both academic research and industrial practices. His role as an educator and mentor has also shaped the careers of numerous engineers and researchers in the field.

Legacy and Future Contributions

Prof. Choe's legacy is marked by his dedication to advancing metallurgical engineering through rigorous research, comprehensive education, and practical industry applications. His ongoing research projects and patents, such as the defect inspection device for tubes and the exhaust gas purification device, highlight his continuous contributions to solving real-world engineering problems. As he continues to lead research and mentor the next generation of engineers, Prof. Choe's future contributions are expected to further the field of failure analysis and metallurgical engineering, ensuring the safety and reliability of metal components in various industries.

 

Notable Publications

Effect of metastable precipitate phase transformation on reheat cracking in SS347H welding 2024

The effect of TCP-σ precipitates on surface pitting and cracking in a Ni-based superalloy turbine blade 2024 (1)

Effect of High Temperature Oxidation on Surface Pit and Recrystallization of Directionally Solidified CM247LC Superalloy in Creep Gauge 2023 (1)

Hydrogen Induced Cracks in Stainless Steel 304 in Hydrogen Pressure and Stress Corrosive Atmosphere 2020 (5)

Analysis of Stress Corrosion Cracking Propagation of SS304 Stainless Steel Using Crack Shape and Etch Pits 2020 (2)

 

 

 

 

Giovanna Maresca | Materials Science | Best Researcher Award

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Dr. Giovanna Maresca | Materials Science | Best Researcher Award

Customs Agency and Monopolies | Italy

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Early Academic Pursuits

Dr. Giovanna Maresca pursued her higher education with a focus on chemistry and materials science. She engaged in significant research from the outset of her career, beginning with her involvement in the project "Hyrides as high-capacity anodes for lithium ion batteries" at "La Sapienza" University of Rome. Her academic journey included synthesizing and studying electrolytic systems compatible with high-capacity hydride-based anodes, laying a strong foundation for her future research endeavors in battery technology.

Professional Endeavors

Dr. Maresca has accumulated extensive professional experience through various prestigious fellowships and research grants across multiple countries:

* Chemist at Customs and Monopolies Agency (ADM), Bologna, Italy (04/18/2022 – CURRENT): Dr. Maresca currently works in this role, applying her expertise in chemistry within the regulatory framework of excise, customs, and monopolies.

* Visiting Fellow at Bernal Institute, University of Limerick, Ireland (01/05/2023 – 30/06/2023): She worked on characterizing post-mortem silicon, hard carbon, and Na-NMO electrodes through XPS and FE-SEM analyses under the supervision of Kevin M. Ryan.

* Research Grant at ENEA Casaccia, Cesano, Italy (04/03/2021 – 18/04/2022): Participated in the European project Si-Drive, focusing on the synthesis and characterization of ionic liquids and innovative electrolytes for lithium batteries. She worked under the guidance of Dr. Giovanni Battista Appetecchi and Prof. Sergio Brutti.

* Samsung Research Fellow at "La Sapienza" University of Rome, Italy (09/30/2016 – 10/30/2020): Worked on the project "Solid-state batteries using novel composite anodes" in collaboration with SAMSUNG, focusing on the synthesis and optimization of electrode composite materials. This fellowship included a period as a visiting fellow at Samsung R&D Institute Japan, studying electrode materials for solid-state batteries under the supervision of Seitaro Ito and Yuichi Aihara.

  • Research Fellow at Politecnico di Turin DISAT – Applied Science Department Technology/ENEA Casaccia, Turin, Italy (15/03/2014 – 14/03/2015): Engaged in the European project MARS-EV, working on the synthesis and characterization of ionic liquids and innovative electrolytes for lithium batteries.

Contributions and Research Focus

Dr. Maresca's research primarily focuses on the development and optimization of materials for energy storage, particularly lithium-ion and solid-state batteries. Her contributions include:

* Synthesis and characterization of innovative electrolytes and electrode materials.

* Development of high-capacity anodes and optimization of composite materials for solid-state batteries.

* Extensive chemical-physical characterization and electrochemical testing of battery components.

* Pioneering research on post-mortem analysis of battery electrodes to improve their performance and longevity.

Accolades and Recognition

Dr. Maresca has been recognized for her significant contributions to battery technology and materials science through prestigious fellowships and research grants. Her collaborations with leading institutions and corporations such as Samsung and ENEA underscore her impact in the field.

Impact and Influence

Dr. Maresca's work has had a profound impact on the development of next-generation energy storage solutions. Her research on high-capacity anodes and solid-state batteries contributes to advancements in electric vehicle technology and sustainable energy storage systems. Her collaborative efforts with international research institutions have also facilitated the exchange of knowledge and innovation in materials science.

Legacy and Future Contributions

Dr. Maresca's continued research and professional activities promise to further enhance the performance and safety of battery technologies. Her ongoing work at the Customs and Monopolies Agency, along with her involvement in cutting-edge research projects, positions her as a key contributor to the future of sustainable energy storage solutions. Her legacy lies in her commitment to advancing battery technology, paving the way for more efficient and durable energy storage systems in the years to come.

 

Notable Publications

Improved Compatibility of α‐NaMnO2 Cathodes at the Interface with Ionic Liquid Electrolytes 2024

Outstanding Compatibility of Hard-Carbon Anodes for Sodium-Ion Batteries in Ionic Liquid Electrolytes 2023 (1)

Silicon‐Based Composite Anodes for All‐Solid‐State Lithium‐Ion Batteries Conceived by a Mixture Design Approach 2023 (5)

Sodium-Conducting Ionic Liquid Electrolytes: Electrochemical Stability Investigation 2022 (8)

Sn/C composite anodes for bulk-type all-solid-state batteries 2021 (9)