Qingshan Pan | Materials Science | Best Researcher Award

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Dr. Qingshan Pan | Materials Science | Best Researcher Award 

Dr. Qingshan Pan | Jiangxi Science & Technology Normal University | China

Dr. Qingshan Pan, Professor at Jiangxi Science & Technology Normal University, is a distinguished researcher specializing in DNA nanomaterials, MOF nanozyme materials, and self-assembled nano/nanogel systems derived from traditional Chinese medicine components. His work focuses on developing antibacterial and anti-inflammatory nanomedicines, advanced wound dressings, and targeted tumor diagnostics and therapies. A recipient of funding from the National Natural Science Foundation of China and multiple provincial grants, Dr. Pan has authored over 20 SCI-indexed publications in leading journals such as Chemical Engineering Journal and ACS Applied Materials & Interfaces, contributing significantly to nanomedicine and precision therapeutics research.

Author Profile

Scopus

Education

Dr. Qingshan Pan’s academic journey began with a strong foundation in chemical engineering, earning his bachelor’s degree from the Department of Chemical Engineering and Technology, Central South University. His early studies nurtured a keen interest in material science, nanotechnology, and their biomedical applications. Driven by a passion for innovation, he pursued doctoral studies at the State Key Laboratory of Chemical Biology and Measurement, Hunan University, specializing in Analytical Chemistry, and graduated with his Ph.D. His doctoral training provided him with advanced expertise in nanoscale materials design, synthesis, and functionalization, particularly for healthcare applications. These formative years equipped him with a multidisciplinary skill set that integrates chemistry, biology, and materials science—an essential foundation for his later breakthroughs in nanomedicine.

Experience

Currently serving as a Professor at Jiangxi Science & Technology Normal University, Dr. Pan is actively involved in teaching, mentoring, and leading high-impact research projects. He has successfully secured funding from prestigious organizations, including the National Natural Science Foundation of China, the Jiangxi Province Outstanding Young Scholars Fund, the Jiangxi Province Natural Science Foundation, and the Education Department. Through these roles, he has developed innovative research programs that bridge fundamental nanoscience with real-world biomedical solutions. Beyond academia, Dr. Pan contributes to the growth of the scientific community by engaging in collaborations with other researchers, fostering interdisciplinary partnerships, and promoting the application of nanotechnology in medicine and healthcare.

Research Focus

Dr. Pan’s research portfolio is broad yet deeply specialized, encompassing DNA nanomaterials, metal–organic framework (MOF) nanozyme materials, and self-assembled nano/nanogel systems derived from traditional Chinese medicine components. These systems have been engineered for antibacterial and anti-inflammatory nanomedicines, advanced antibacterial dressings, and precision tumor diagnosis and therapy.

His innovative approach to combining traditional Chinese medicine with cutting-edge nanotechnology has led to the development of hybrid nanomaterials that exhibit unique bioactive properties, enhanced stability, and targeted delivery capabilities. By integrating DNA nanotechnology with MOF-based nanozymes, his work addresses key challenges in biomedical applications, such as targeted drug release, controlled therapeutic activity, and dual-function systems capable of both diagnosis and treatment. These contributions not only advance the frontiers of nanomedicine but also provide new strategies for combating bacterial infections, reducing inflammation, and improving cancer therapy outcomes.

Award and Recognition

Dr. Pan’s scientific achievements are reflected in his impressive publication record, with over 20 SCI-indexed papers in internationally renowned journals, including Chemical Engineering Journal and ACS Applied Materials & Interfaces. His work is recognized for its high citation value, innovative experimental design, and significant potential for translational application in clinical medicine. Receiving funding from multiple prestigious agencies underscores his reputation as a leading figure in nanomedicine research. His role as a principal investigator in national and provincial projects highlights his ability to conceive, lead, and execute complex research initiatives that meet rigorous scientific standards.

Impact and Influence

The impact of Dr. Pan’s research extends far beyond academic citations. His nanomedicine platforms have the potential to revolutionize how bacterial infections, inflammation, and tumors are diagnosed and treated. The antibacterial dressings developed in his lab could play a crucial role in preventing hospital-acquired infections and promoting faster wound healing. His tumor-targeted nanotherapies are paving the way for minimally invasive and highly specific cancer treatments, reducing side effects while improving efficacy. Furthermore, by integrating bioactive compounds from traditional Chinese medicine into modern nanocarriers, Dr. Pan is contributing to a new paradigm in personalized and culturally rooted healthcare innovation.

Publications 

Transition Metal Sulfide-Based Nanozymes: From Design Strategies to Applications in Chronic Wound Healing

Author: Yuying Zhang, Renxi Li, XianXi Li, Pengwu Zheng, Wufu Zhu, Cunpeng Nie, Qingshan Pan
Journal: ACS Applied Nano Materials
Year: 2025

Review of Metal-Polyphenol Self-Assembled Nanoparticles: Synthesis, Properties, and Biological Applications in Inflammatory Diseases.

Author: Li Wan, Shizhe Li, Jiawei Du, Anqi Li, Yujie Zhan, Wufu Zhu, Pengwu Zheng, Dan Qiao, Cunpeng Nie, Qingshan Pan
Journal: ACS Biomaterials Science & Engineering
Year: 2025

Photothermally Enhanced Cascaded Nanozyme-Functionalized Black Phosphorus Nanosheets for Targeted Treatment of Infected Diabetic Wounds.

Author: Chunping Wen, Yan Zhang, Luogen Lai, Xuan Zhang, Yijun Liu, Qiuyan Guo, Rujue Peng, Yating Gao, Xufei Zhang, Yan He, Shan Xu, Dan Qiao, Pengwu Zheng, Qingshan Pan, Wufu Zhu
Journal: Advanced Healthcare Materials
Year: 2025

Conclusion

Dr. Qingshan Pan’s remarkable journey from his foundational studies in chemical engineering to his pioneering research in analytical chemistry and nanomedicine reflects a career marked by curiosity, dedication, and innovation. His expertise in designing DNA nanomaterials, MOF nanozyme platforms, and self-assembled nanogels bridges the gap between advanced material science and practical biomedical applications, addressing critical challenges in antibacterial, anti-inflammatory, and tumor-targeted therapies. Through his leadership in prestigious national and provincial research projects, his extensive scholarly publications, and his commitment to translating research into impactful solutions, Dr. Pan has firmly established himself as a trailblazer in interdisciplinary science. His work not only elevates the academic standing of Jiangxi Science & Technology Normal University but also contributes meaningfully to global advancements in nanotechnology and precision medicine. As his career progresses, Dr. Pan is poised to expand his influence, inspiring future scientists while continuing to innovate at the intersection of chemistry, biology, and medicine.

Wanting Zhu | Materials Science | Best Researcher Award | 13543

Posted on by Research Awards

Prof. Wanting Zhu | Materials Science | Best Researcher Award 

Prof. Wanting Zhu, Wuhan University of Technology (WUT), China

Prof. Wanting Zhu is a distinguished Professor of Materials Science and Engineering at the Wuhan University of Technology (WUT), where she conducts advanced research at the State Key Laboratory of Advanced Technology for Materials Synthesis and Processing. Her expertise lies in thermoelectric materials and device engineering, with a particular focus on artificially tilted-structure transverse thermoelectric devices. She has pioneered high-throughput screening methods and established key design principles for these systems across various application scenarios. With over ten SCI-indexed publications, including recent works in ACS Applied Materials & Interfaces and Journal of Power Sources, Prof. Zhu is a recognized leader in optimizing thermoelectric performance and device stability.

Author Profile

Scopus

Education

Prof. Wanting Zhu’s academic journey in materials science began with a strong inclination towards fundamental research and practical engineering applications. From the outset of her education, she demonstrated a profound interest in energy materials, particularly those that contribute to sustainable and efficient thermal-to-electric energy conversion. Her early academic training equipped her with a solid foundation in thermodynamics, solid-state physics, and electronic materials, laying the groundwork for what would become a career at the intersection of cutting-edge materials research and real-world technological applications. Her curiosity and drive for innovation during her formative academic years eventually led her to explore thermoelectric materials—an area both scientifically rich and highly relevant to global energy challenges.

Experience

Currently serving as a Professor of Materials Science and Engineering at the Wuhan University of Technology (WUT), Prof. Zhu is affiliated with the State Key Laboratory of Advanced Technology for Materials Synthesis and Processing. In this role, she actively leads high-impact research focused on the design, fabrication, and optimization of thermoelectric devices, especially those with artificially tilted multilayer structures. She has emerged as a leading figure in her field, bridging theoretical insight and experimental prowess.

Her lab not only conducts fundamental research but also engages in the development of functional materials for real-world applications in electronics, energy harvesting, and thermal management systems. Prof. Zhu also plays a vital role in mentoring graduate students and postdoctoral researchers, fostering a collaborative and innovation-driven research environment. Her commitment to scientific advancement is evident in her hands-on leadership, guiding both applied research and long-term academic training.

Research Focus

She has made pioneering contributions in developing artificially tilted multilayer thermoelectric systems, which exhibit transverse thermoelectric effects. Her research elucidates both the structural design principles and manufacturing techniques necessary for tailoring these devices to specific energy and thermal environments. Prof. Zhu developed an innovative high-throughput screening method for optimizing the performance of thermoelectric devices, significantly accelerating materials discovery and device fabrication. This method enables rapid identification of effective material combinations and geometric configurations, increasing the efficiency of research and reducing production costs. She has also extended her research into materials with broadband infrared radiation capabilities, such as spinel ferrites, for thermal regulation in electronics—demonstrating the versatility and interdisciplinary reach of her work.

Her publications, appearing in Journal of Power Sources, ACS Applied Materials & Interfaces, and Ceramics International, are a testament to her deep expertise and forward-thinking approach.

Award and Recognition

Prof. Zhu has authored more than 10 SCI-indexed publications as a first or corresponding author, and her research has been widely cited in the fields of thermoelectricity and materials engineering. Her scientific contributions have positioned her as a thought leader in thermoelectric device design in China and internationally.

Her work has gained attention not just for its academic rigor but also for its potential applications in next-generation wearable electronics, energy harvesters, and electronic cooling systems. She is frequently invited to collaborate and review for leading journals, reflecting her growing influence and professional standing in the global research community.

Publications

📘Enhancing electrical properties of flexible BiSbTe/epoxy composite films via liquid-phase extrusion – Journal of power resources(2024).

📘Optimizing Room‐Temperature Thermoelectric and Magnetocaloric Performance via Constructing Multi‐Scale Interfacial Phases in LaFeSi/BiSbTe Thermo‐Electro‐Magnetic Refrigeration Materials – Advanced functional materials(2024).

📘Excellent thermoelectric performance of Fe2NbAl alloy induced by strong crystal anharmonicity and high band degeneracy – Quantum Materials(2024).