Baoling Jia | Materials Science | Best Researcher Award

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Dr. Baoling Jia | Materials Science | Best Researcher Award

Lecturer, Lanzhou University of Technology, China

Baoling Jia is a dedicated lecturer and PhD student at Lanzhou University of Technology, known for her innovative contributions to biomedical materials research. She specializes in the development and modeling of microneedle (MN) systems designed for enhanced transdermal drug delivery and biosensing. Through interdisciplinary research that bridges materials science and biomedical engineering, Jia is advancing medical technology with practical, patient-friendly solutions. Her work is characterized by precision, sustainability, and an emphasis on improving mechanical and biological performance through smart material design and fabrication.

Professional Profile

Education 🎓

Jia completed her Bachelor’s and Master’s degrees in Materials Science and Engineering at Lanzhou University of Technology. She is currently pursuing her PhD at the same institution, where she continues to focus on biomedical material design, particularly UV-curable polymers and their use in medical applications. Her education has been rooted in the principles of polymer chemistry, mechanical modeling, and biomedical systems, forming a solid foundation for her cutting-edge microneedle research.

Experience 💼

Baoling Jia With a combined role as a university lecturer and a PhD researcher, Jia plays an active part in both academic instruction and scientific inquiry. She has participated in multiple interdisciplinary projects focusing on microneedle development for therapeutic and diagnostic applications. Her experience includes hands-on work with photopolymerization, 3D printing, and the mechanical testing of polymer structures, equipping her with the technical depth needed to solve real-world medical material challenges. Jia is recognized for her collaborative spirit, frequently working with teams across materials science, mechanical engineering, and biomedicine.

Research Interests 🔬

Baoling Jia focuses on biomedical materials, particularly the design and fabrication of UV-curable polymer microneedles. Her research explores staggered microneedle structures for better skin penetration and comfort, along with biocompatibility and mechanical performance testing. She also applies 3D printing and photopolymerization techniques to develop scalable, minimally invasive transdermal drug delivery systems and biosensors aimed at improving long-term healthcare solutions.

Publications Top Note📄

  • Jia, Baoling; Xia, Tiandong; Xu, Yangtao; Li, Bei. Staggered Design of UV–Curable Polymer Microneedle Arrays with Increased Vertical Action Space. Polymers, 2025. (Open Access)
    Summary: This study presents a novel staggered architecture for UV-curable polymer microneedle arrays to enhance vertical action space. The design improves mechanical penetration efficiency and user comfort, offering potential for advanced transdermal delivery and biosensing technologies.

Conclusion 🏁

Baoling Jia is a promising early-career researcher whose contributions to biomedical materials are poised to make a lasting impact on healthcare technologies. Her work on staggered UV-curable microneedle systems represents a significant step forward in medical material design, blending innovation, efficiency, and patient-centered application. With a strong academic foundation, practical research experience, and a clear focus on solving real-world problems, Jia exemplifies the qualities of a forward-thinking biomedical engineer. Her work will continue to influence the future of non-invasive therapeutics and diagnostics, making her a highly suitable nominee for recognition and support in the field of biomedical research.

Tiandong Xia | Materials Science | Best Researcher Award

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Prof. Dr. Tiandong Xia | Materials Science | Best Researcher Award

Professor, Lanzhou University of Technology, China

Professor Tiandong Xia is a leading academic and doctoral supervisor in the Department of Materials Science and Engineering at Lanzhou University of Technology. With deep expertise in biomedical materials, he has built a career grounded in innovation and scientific inquiry. His research contributions span the synthesis, processing, and application of functional materials, with a focus on microneedle technology, biocompatibility, and electrochemical performance. Recognized for his collaborative and interdisciplinary approach, Professor Xia has published impactful research articles that bridge materials science and medical technology.

Professional Profile

Education 🎓

Professor Xia pursued his entire academic formation in the field of Materials Science and Engineering, completing his undergraduate, master’s, and doctoral degrees with academic distinction. His doctoral work focused on functional materials for high-performance biomedical applications, establishing a foundation for his future career as a researcher and mentor. His educational background is marked by a commitment to both theoretical understanding and applied research, which continues to guide his scholarly pursuits today.

Experience 🏫

Over the years, Professor Xia has played an instrumental role in advancing materials science research at Lanzhou University of Technology. As a doctoral supervisor, he has mentored numerous postgraduate students, fostering a research culture of curiosity and precision. He is frequently involved in national and international research collaborations, contributing his expertise in biomaterials engineering to address complex challenges in healthcare technologies. His academic roles also include curriculum development, lab oversight, and participation in scientific committees focused on materials innovation.

Research Interests 🔬

Professor Xia’s research bridges materials science, bioengineering, and applied chemistry, with a focus on developing smart, safe, and effective materials for biomedical use. His key areas include microneedles for transdermal sensing and drug delivery, electrode and surface modification, oxidation resistance of metal alloys, and nano-structured coatings and biosensors. His work aims to advance minimally invasive diagnostic and therapeutic technologies that address real-world medical challenges.

Publications Top Notes📚

  • ia, Baoling; Xia, Tiandong; Wang, Xiaohui; Xu, Yangtao; Li, Bei. Investigation of biosensing properties in magnetron sputtered metallized UV-curable polymer microneedle electrodes. Journal of Biomaterials Science, Polymer Edition, 2024.
    Summary: This study explores the fabrication and biosensing performance of UV-curable polymer microneedle electrodes metallized via magnetron sputtering. The work demonstrates promising electrochemical properties suitable for minimally invasive biosensor applications.

  • Zhang, Han; Gao, Yueyue; Qiao, Jisen; Xia, Tiandong. Effect of high temperature heat treatment on microstructure and mechanical properties of electrodeposited nickel. Jinshu Rechuli/Heat Treatment of Metals, 2023.
    Summary: This article investigates how high-temperature heat treatment affects the microstructure and mechanical behavior of electrodeposited nickel. Findings indicate that controlled heat treatment enhances grain growth and mechanical strength.

  • Jia, Baoling; Xia, Tiandong; Wang, Xiaohui; Xu, Yangtao; Guo, Zhenyu. Morphology design of polymer microneedle arrays: Key factors from the application perspective. Review Article, Year Not Specified.
    Summary: This review examines critical factors influencing the morphology of polymer microneedle arrays, such as shape, size, and structural design, with a focus on optimizing their functionality for transdermal drug delivery and biosensing applications.

  • Xie, Xiao; Wang, Xiaojun; Xia, Tiandong. Effects of Rare Earth Y on Oxidation Resistance of Cr20Ni80 Electrothermal Alloy at High Temperature. Tezhong Zhuzao Ji Youse Hejin/Special Casting and Nonferrous Alloys, 2022.
    Summary: The paper analyzes the impact of rare earth element yttrium on the high-temperature oxidation resistance of Cr20Ni80 electrothermal alloy. Results show that Y addition significantly enhances surface stability and oxidation resistance under thermal stress.

Conclusion 🏆

Professor Tiandong Xia has built a distinguished career in materials science, particularly in the development of biomedical materials that serve both clinical and industrial purposes. His innovative research on microneedle technologies and alloy modification has not only advanced academic knowledge but also opened new possibilities in non-invasive medical diagnostics and high-performance engineering applications. His commitment to excellence, mentorship, and collaborative research makes him a compelling candidate for any award recognizing contributions to science and technology.

DongYu Hou | Chemical Engineering | Best Researcher Award

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Dr. DongYu Hou | Chemical Engineering | Best Researcher Award

Phd Student, School of Electrical and Electronic Engineering, Harbin University of Science and Technology, China

Dongyu Hou is a dedicated and emerging researcher currently pursuing his Ph.D. in Electrical Engineering at the School of Electrical and Electronic Engineering, Harbin University of Science and Technology. With a strong academic background in materials and chemical engineering, Dongyu has focused his research on high-performance materials for energy storage and thermal insulation applications. His work emphasizes the integration of low-temperature plasma technology with advanced material systems for electric vehicles and electronic components. He has contributed to a significant research publication in the Journal of Energy Storage (2025), co-authored a pending Chinese invention patent, and received the Outstanding Graduate Award of Yunnan Province, establishing himself as a young leader in materials science and electrical engineering.

Profile

Scopus

🎓 Education

Dongyu holds a master’s degree in Materials and Chemical Engineering from Kunming University of Science and Technology 🎓. During his graduate studies, he developed a plasma-assisted process for regenerating lithium-ion battery cathode materials, which significantly reduced processing time and improved material performance. He is currently pursuing a Ph.D. in Electrical Engineering at Harbin University of Science and Technology 📘. His doctoral work focuses on the development of high thermal conductivity insulating materials, particularly for use in electric vehicle motors, aiming to address challenges in heat management and energy efficiency within compact power systems.

🧪 Experience

Throughout his academic journey, Dongyu has worked on a wide range of interdisciplinary research projects at the intersection of chemical engineering, plasma physics, and electrical materials. Under the mentorship of Professor Chengxu Zhang (2021–2024) and Professor Yu Feng (from 2024), Dongyu has sharpened his theoretical and experimental skills. He has explored material design strategies such as polymer blending, plasma surface modification, and composite optimization. Dongyu’s approach combines innovative engineering solutions with sustainable practices, focusing on scalable technologies for the energy sector ⚙️.

🔍 Research Interests

  • Low-temperature plasma applications for material modification

  • Recycling technologies for lithium-ion batteries

  • Dielectric energy storage materials for high-temperature use

  • High thermal conductivity composites for electrical insulation
    Currently, he is investigating ways to enhance the thermal conductivity and dielectric efficiency of polymers through advanced filler design and multilayer architectures. His long-term goal is to contribute to the development of sustainable, high-performance materials for the energy storage and automotive industries 🔋🚗.

📄 Selected Publication

“Improvement of high-temperature energy storage performance of PC/FPE all-organic composite dielectrics based on functional multilayer structure design”, Journal of Energy Storage, 2025.
Authors: Wenchao Zhang, Qingguo Chen, Yu Feng, Dongyu Hou et al.
This study introduces a novel multilayer structure combining polycarbonate (PC) and fluorinated polyether (FPE) to improve dielectric performance under high-temperature conditions. The research proposes a functional layering method that enhances energy storage density and breakdown strength while maintaining thermal stability. Dongyu contributed significantly to the experimental methodology and thermal conductivity analysis. This paper marks a notable advancement in the development of polymer-based energy storage systems that are both efficient and thermally resilient. The publication has already begun to attract scholarly attention and is expected to be widely cited due to its relevance to next-generation electronic and automotive systems 🔬📈.

🏁 Conclusion

Dongyu Hou is a promising early-career researcher who demonstrates a rare combination of academic rigor, innovative thinking, and commitment to sustainable engineering. His current Ph.D. research on high-performance insulating materials is aligned with pressing technological challenges in electric vehicle systems and power electronics. His co-authored 2025 publication in the Journal of Energy Storage represents a significant scientific contribution and reflects his ability to collaborate effectively on interdisciplinary projects. With a patent application under review and membership in esteemed professional organizations such as the IEEE and the Plasma and their Applications Committee, Dongyu remains actively engaged with the scientific community. His achievements so far, combined with his strong potential for future impact, make him a worthy candidate for the Best Researcher Award 🏅.