Xueliang Wang | Nanosensors and Actuators | Research Excellence Award

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Prof. Xueliang Wang | Nanosensors and Actuators | Research Excellence Award

 Professor | Heze University | China

Prof. Xueliang Wang is a highly cited researcher in the field of electroanalytical chemistry and biosensor technology, with 838 citations, 64 publications, and an h-index of 16. His research focuses on the design, fabrication, and application of advanced electrochemical sensors and biosensors, with significant contributions to detecting DNA hybridization, DNA damage, enzymes, antibiotics, catecholamines, and various biomolecules. A major part of his scientific work involves creating nano-engineered biointerfaces using innovative materials such as Fe@Fe₂O₃ core–shell nanostructures, Au–Pt alloy nanoparticles, carbon nanotubes, nanozirconia, graphene hybrids, and conductive polymer films. These advanced interfaces significantly enhance sensitivity, selectivity, and electron-transfer performance in biosensors. His research has delivered new strategies for sequence-specific DNA detection, toxicity assessment, antioxidant evaluation, and hydrogen peroxide sensing, contributing valuable methods for biomedical analysis, food safety, and environmental monitoring. Prof. Xueliang Wang has published extensively in high-impact journals, including Biosensors and Bioelectronics, Analytica Chimica Acta, Electrochimica Acta, Sensors and Actuators B, and Electroanalysis, where his studies have been recognized for pioneering approaches to nano-enabled sensing platforms. His works often integrate characterization tools such as SEM, TEM, XRD, CV, DPV, EIS, and UV-Vis spectroscopy to explore molecular interactions and biosensing mechanisms. He has played leading roles in multiple National Natural Science Foundation of China (NSFC) projects, including the development of electrochemical DNA biosensors, transgene detection systems, antioxidant activity sensors, and LAMP-assisted sensing technologies. His leadership in these projects reflects his strong expertise in R&D, nanomaterial-based sensor development, and interdisciplinary analytical innovation. Prof. Xueliang Wang’s scientific contributions have earned him prestigious recognitions such as the Heze Youth Science and Technology Award and the Shandong Outstanding Scientific Achievement Award. He also contributes to the research community through peer-review activities, collaborative projects, and continuous innovation in biosensor technology, establishing him as a respected figure in analytical chemistry and nanomaterials-based sensor research.

Profiles: Scopus | ORCID | ResearchGate | Sci Profiles | Scilit

Featured Publications

1. Li, H., Gao, X., Wang, T., Shi, Z., Bai, J., Wang, Z., & Wang, X. (2025, October 22). NiMoO4 nanosheets through co-doping of AlMnFe engineering for enhanced bifunctional electrochemical catalysis for overall water splitting. Fuel, 406. https://doi.org/10.1016/j.fuel.2025.137223

2. Zou, N., Li, X., Xu, M., Wang, Z., Zhang, J., & Wang, X. (2025, June 23). Selectivity optimization of real-time and continuous sensing of endogenous H2S in biological fluids. Microchimica Acta, 192(7), 1–14. https://doi.org/10.1007/s00604-025-07298-4

3. Sun, Y., Wang, X., & Lee, H. L. (2025, June 16). Fabrication of sustainable ternary magnetic BiOCl/BiOBr/CuFe2O4 heterostructures for degradation of tetracycline. Langmuir, 41(25), 16073–16089. https://doi.org/10.1021/acs.langmuir.5c01184

4. Meng, F., Li, X., Zou, N., & Wang, X. (2025, May 6). Protein profiling by nanopore-based technology. Analytical Chemistry, 97(19), 10110–10125. https://doi.org/10.1021/acs.analchem.5c00992

5. Li, H., Gao, X., Zheng, S., Li, J., Wang, Z., Shi, Z., Bai, J., & Wang, X. (2025, March 3). Preparation of Fe(OH)3/Ni3S2/NiS heterostructure on an iron nickel foam as long-life trifunctional electrocatalysts for seawater and urea splitting. Journal of Alloys and Compounds, 1020. https://doi.org/10.1016/j.jallcom.2025.179554

Jianwei Chen | Nanophotonics and Nanoelectronics | Best Researcher Award

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Dr. Jianwei Chen | Nanophotonics and Nanoelectronics | Best Researcher Award

Lecturer | Zhejiang Ocean University | China

Dr. Jianwei Chen is a dedicated researcher and lecturer at Zhejiang Ocean University, China, whose work focuses on the development of micro- and nanostructured electronic and photonic devices based on van der Waals (vdW) two-dimensional materials. His research contributes to the advancement of terahertz focal plane array devices and the engineering of high-performance heterostructures for next-generation optoelectronic technologies. With 123 citations, 9 publications, and an h-index of 6, Dr. Jianwei Chen has made impactful contributions to materials science and applied physics. His recent works published in reputed journals such as Materials Today Physics and ACS Applied Materials & Interfaces explore the design, modulation, and optimization of vdW 2D material interfaces and heterostructures, establishing a foundation for their practical use in terahertz imaging and advanced photonics. Earlier in his career, his studies on calcium alumino-titanate and bauxite–SiC composites significantly contributed to the understanding of microstructural control and mechanical performance in ceramic refractories. Dr. Jianwei Chen’s ongoing research integrates electronic engineering, material science, and device physics, emphasizing innovative interface engineering and controlled synthesis of high-quality bubble-free conducting vdW heterostructures. His contributions are recognized through distinctions such as the Outstanding Master’s Thesis Award by the China Society of Metallurgical Education (2020). He actively participates in research collaborations and academic dissemination, promoting advancements in nano-optoelectronics and 2D materials-based device fabrication. His scholarly output reflects a commitment to bridging fundamental research with functional device applications, particularly in terahertz imaging and nanophotonics, aligning with global trends in advanced material innovation and device miniaturization.

Profiles: Scopus | ORCID

Featured Publications

  • Chen, J., Guo, Y., Su, Y., et al. (2025). Interface interaction, design, modulation, and optimization of van der Waals two-dimensional materials. Materials Today Physics, 58, 101878.

  • Chen, J., Liu, L., Chen, H., et al. (2024). Controlled preparation of high-quality bubble-free and uniform conducting interfaces of vertical van der Waals heterostructures of arrays. ACS Applied Materials & Interfaces, 16, 10877–10885.

  • Chen, J., Zhao, H., Zhang, H., et al. (2018). Effect of partial substitution of calcium alumino-titanate for bauxite on the microstructure and properties of bauxite-SiC composite refractories. Ceramics International, 44, 2934–2940.

  • Chen, J., Zhao, H., Zhang, H., et al. (2018). Effect of the calcium alumino-titanate particle size on the microstructure and properties of bauxite-SiC composite refractories. Ceramics International, 44, 6564–6572.

  • Chen, J., Zhao, H., Zhang, H., et al. (2018). Sintering and microstructure characterization of calcium alumino-titanate-bauxite-SiC composite refractories. Ceramics International, 44, 10934–10939.

 

Hai-Long Jiang | Nanosensors and Actuators | Best Researcher Award

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Dr. Hai-Long Jiang | Nanosensors and Actuators | Best Researcher Award

Ph.D. Candidate, Qilu University of Technology, China

Dr. Hai-Long Jiang is an active researcher at Qilu University of Technology whose scientific contributions span analytical chemistry, environmental science, and materials innovation. His research emphasizes the development of advanced analytical and remediation technologies for environmental pollutants, food contaminants, and pharmaceutical substances, integrating chemical sensing, material design, and computational approaches. His work is directed toward building sustainable systems for ecological safety, health risk assessment, and industrial material evaluation. Dr. Hai-Long Jiang’s research primarily addresses critical challenges in pollutant detection, toxicological assessment, and safety monitoring through the design of functional materials such as covalent organic frameworks (COFs), metal–organic frameworks (MOFs), and nanomaterials. His recent studies demonstrate novel strategies for accelerating the crystallization of magnetic fluorine-functionalized 3D COFs to efficiently capture trace benzoylurea insecticides in beverages, as well as the facile synthesis of aluminum-based MOFs for adsorbing artificial sweeteners. Additionally, his comprehensive reviews on nanomaterial-based sensors for heavy metal ion detection provide valuable insights into next-generation sensing platforms with enhanced precision and environmental relevance. He has published 36 scientific papers in internationally recognized journals including Chemical Engineering Journal, Food Chemistry, Analytica Chimica Acta, and Microchemical Journal, where he has frequently served as first or corresponding author. His representative works highlight the integration of experimental and computational methodologies to uncover the mechanisms behind pollutant adsorption and detection. With a total of 1,141 citations and an h-index of 14, Dr. Hai-Long Jiang’s publications reflect a growing impact in analytical and environmental chemistry. His collaborations with more than 90 co-authors worldwide further underscore his multidisciplinary approach and scientific influence. Through his innovative exploration of material-based sensing, pollutant remediation, and safety evaluation, Dr. Hai-Long Jiang has established himself as a promising researcher advancing analytical methods and sustainable technologies for environmental and health protection.

Profile: Scopus

Featured Publications

  • Liu, Z., Liu, L., Dong, Y., Li, Y., Zhang, C., Wang, X.-L., Zhao, L., Jiang, H.-L., Wu, Y.-N., Chen, X., Li, F., & Zhao, R.-S. (2025). Ionic liquids accelerate the crystallization of a magnetic fluorine-functionalized 3D covalent organic framework for efficient capture of trace benzoylurea insecticides in juices and beverages. Chemical Engineering Journal, 524, 169460.

  • Luo, X.-W., Kang, F.-S., Wang, X.-L., Jiang, D.-F., Lin, Y.-L., Jiang, H.-L., & Zhao, R.-S. (2025). Facile synthesis of aluminum-based metal–organic frameworks for high adsorption of artificial sweeteners in beverages and seasonings: Integrating experimental and computational study. Microchemical Journal, 218, 115536.

  • Liu, D.-M., Dong, C., & Jiang, H.-L. (2025). Nanomaterial-based sensors for heavy metal ions analysis. Microchemical Journal, 218, 115511.

 

QinghuaWei |Nanosensors and Actuators | Best Researcher Award

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Assoc. Prof. Dr. Qinghua Wei | Nanosensors and Actuators | Best Researcher Award

Associate Professor at Northwestern Polytechnical University, China

Dr. Qinghua Wei, a distinguished Doctor of Engineering and doctoral supervisor, is recognized for his pioneering research in composite materials and biological additive manufacturing. As a recipient of the “Aerospace New Star” award from Northwestern Polytechnical University, he has led over ten major national projects and authored more than 80 high-impact publications, with over 1,600 SCI citations. His innovations have yielded 23 national patents, nine of which have been successfully commercialized, and ten software copyrights. Dr. Wei’s outstanding contributions have earned him prestigious honors, including the First Prize of the National Technology Invention Award and multiple provincial science and technology awards. His interdisciplinary work integrates materials science, 3D bioprinting, and biomedical engineering, with significant translational value. Listed among the world’s top 2% scientists by Stanford University, Dr. Wei exemplifies research excellence and innovation, with a commitment to advancing scientific knowledge and nurturing future scholars in advanced manufacturing and biomaterials.

Professional Profile 

Scopus Profile

Education

Dr. Qinghua Wei holds a Doctorate in Engineering, which has laid the foundation for his extensive academic and research career. His educational journey reflects a solid grounding in materials science, mechanical engineering, and manufacturing technologies. His doctoral training equipped him with the theoretical knowledge and practical skills necessary to address complex problems in composite material design and additive manufacturing. Through rigorous academic preparation, Dr. Wei developed a keen interest in integrating multiple disciplines such as biomaterials, mechanics, and process engineering. His academic background also provided the platform for his future role as a doctoral supervisor, mentoring graduate students and guiding innovative research projects. His education has not only shaped his technical capabilities but also cultivated his analytical thinking and leadership qualities, enabling him to lead national-level projects and secure recognition within the scientific community. His commitment to lifelong learning continues to inform his work in advanced manufacturing and biomedical applications.

Professional Experience

Dr. Qinghua Wei is a seasoned researcher and doctoral supervisor at Northwestern Polytechnical University, where he also earned recognition through the “Aerospace New Star” science and technology talent program. Over the course of his career, he has led more than ten high-level research projects, including those funded by the National Natural Science Foundation of China and the State Key Research and Development Program. His responsibilities extend beyond research to include project management, academic mentorship, and technology transfer. Dr. Wei has an impressive track record of publishing over 80 peer-reviewed articles and two academic monographs, which have earned wide citation and acclaim. He has also played a pivotal role in translating research into practice, with 23 national invention patents—nine of which have been successfully commercialized. His experience reflects a balanced integration of scientific inquiry, educational mentorship, and innovation-driven entrepreneurship, positioning him as a thought leader in additive manufacturing and materials science.

Research Interest

Dr. Qinghua Wei’s research interests lie at the intersection of composite materials, 3D bioprinting, and biomedical manufacturing. His work focuses on the multi-scale design and functional modification of composite materials for high-performance applications. A major area of emphasis is the development of biological additive manufacturing technologies, including novel bio-inks, smart hydrogels, and multi-material extrusion systems for 3D printing. He has contributed significantly to tissue engineering, particularly in the fabrication of bone scaffolds, skin substitutes, and soft tissue constructs using biocompatible hydrogels. His work also explores the optimization of printing parameters through numerical modeling and simulation, ensuring both structural integrity and cell viability. By integrating mechanical design, material science, and bological systems, Dr. Wei is pioneering advanced solutions with both clinical and industrial relevance. His interdisciplinary research not only advances fundamental science but also offers practical tools and technologies that address challenges in healthcare, aerospace, and precision manufacturing.

Award and Honor

Dr. Qinghua Wei has received numerous awards and honors that underscore his contributions to science and technology. Most notably, he was awarded the First Prize of the National Technology Invention Award in 2019, a prestigious national recognition of groundbreaking research with significant impact. He has also received the Second Prize of the Shaanxi Provincial Natural Science Award (2024) and the First Prize of the Shaanxi Provincial University Science and Technology Award in 2024, 2020, and 2016, demonstrating sustained excellence over the years. In 2023, his research was evaluated as qualified by the International Association for Science and Technology Promotion of China. Furthermore, his scientific output has earned him a place in Stanford University’s list of the world’s top 2% scientists, reflecting both national and international acknowledgment. These honors affirm Dr. Wei’s leadership in his field and validate the relevance, originality, and societal value of his research contributions.

Conclusion

In summary, Dr. Qinghua Wei is an accomplished researcher whose academic rigor, innovative spirit, and translational impact make him a standout figure in engineering and applied sciences. With a solid educational foundation, extensive project leadership, and cutting-edge interdisciplinary research, he bridges theory and real-world application in fields such as composite materials and 3D bioprinting. His work has led to high-impact publications, patent commercialization, and influential collaborations, reflecting both depth and breadth in his expertise. Dr. Wei’s career is marked by a consistent trajectory of excellence, as evidenced by prestigious national awards and global scientific recognition. As a mentor, inventor, and thought leader, he continues to shape the future of advanced manufacturing and biomedical engineering. His accomplishments not only enhance academic knowledge but also contribute to technological innovation with societal benefits. Dr. Wei is undoubtedly a strong candidate for major research accolades and an exemplar of excellence in modern engineering research.

Publications Top Notes

  • Title: A triple-network PVA/cellulose nanofiber composite hydrogel with excellent strength, transparency, conductivity, and antibacterial properties

    • Authors: Li, Mingyang; Wang, Yanen; Wei, Qinghua; Liu, Zhisheng

    • Year: 2025

  • Title: 3D printing of microstructured polyacrylamide/sodium alginate/lithium chloride composite hydrogels for nanofriction generator and e-skin

    • Authors: Chen, Xiaohu; Wang, Qinglin; Ma, Shuai; Xu, Yan; Wang, Yanen

    • Year: 2025

    • Citations: 1

  • Title: Investigation of wet-heat coupling and hygroscopic behavior of moso bamboo

    • Authors: Hong, Qi; Wei, Qinghua; Lan, Xianwei; Yuan, Jing

    • Year: 2025

  • Title: Optimal design of multi-biomaterials mixed extrusion nozzle for 3D bioprinting considering cell activity

    • Authors: Wei, Qinghua; An, Yalong; Zhao, Xudong; Zhang, Juan; Cui, Ning

    • Year: 2025

  • Title: Influence of particle size distribution on hydroxyapatite slurry and scaffold properties fabricated using digital light processing

    • Authors: Liu, Minyan; Wang, Yanen; Zhang, Haonan; Liu, Zhisheng; Liu, Xiaowu

    • Year: 2024

    • Citations: 3

  • Title: Research on the flow behavior of bio-ink inside the extrusion nozzle during printing

    • Authors: Wei, Qinghua; An, Yalong; Li, Mingyang; Zhao, Xudong

    • Year: 2024

  • Title: Optimization of hydrogel extrusion printing process parameters based on numerical simulation

    • Authors: Wei, Qinghua; Li, Mingyang; An, Yalong; Zhao, Xudong; Sun, Daocen

    • Year: 2024

Assoc. Prof. Dr. Ali Kazempour | Nanotechnology | Best Researcher Award

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Assoc. Prof. Dr. Ali Kazempour | Nanotechnology | Best Researcher Award

Assoc. Prof. Dr. Ali Kazempour, Payame Noor University, Iran

Dr. Ali Kazempour 🎓 is an Associate Professor at the Physics Department of Payame Noor University, Tehran, Iran 🇮🇷. He also serves as the Director of the Nanostructured Coatings Institute 🧪. With a Ph.D. in Physics from Isfahan University of Technology, his research bridges theoretical physics and nanotechnology 🔬. Specializing in first-principles simulations, nonlinear optics, and quantum computations ⚛️, he actively contributes to advancing material science. Through international collaborations 🌍 and active seminar participation, he continues to make significant strides in semiconductor physics, ultrafast dynamics, and defect analysis in nanostructures 💡.

Professional Profile:

Scopus

🏅 Suitability Summary

Dr. Ali Kazempour stands out as a distinguished researcher whose work seamlessly connects theoretical physics, nanotechnology, and computational materials science. His diverse academic background and leadership role as Director of the Nanostructured Coatings Institute reinforce his stature as a leading figure in his field. His research addresses critical areas such as ultrafast dynamics, defect analysis, and quantum computations, which are central to many next-generation technologies.

🔹 Education & Experience 

🎓 Ph.D. in Physics (2005–2011)

  • Isfahan University of Technology

  • Thesis: First-principles study of charged oxygen vacancies in Rutile TiO₂ & structural stability of MnAs nanowires

🎓 M.Sc. in Physics (2003–2005)

  • Isfahan University of Technology

  • Thesis: Wavelet Transform Modulus Maxima analysis of Interbeat Interval Time Series

🎓 B.Sc. in Physics (1999–2003)

  • Isfahan University of Technology

👨‍🏫 Current Position:

  • Associate Professor, Physics Department, Payame Noor University

  • Director, Nanostructured Coatings Institute, PNU

🌏 Scientific Visits:

  • Ulsan National Institute of Science and Technology, South Korea 🇰🇷

  • Fritz Haber Institute, Max Planck Society, Berlin 🇩🇪

🔹 Professional Development 

Dr. Kazempour’s professional growth is deeply rooted in a strong commitment to continuous learning and global engagement 🌐. He has participated in more than ten national and international workshops, including those organized by ICTP in Italy 🇮🇹 and Humboldt-Kolleg 🇩🇪, focusing on advanced computational methods, quantum optics, and density functional theory 🖥️📊. His scientific visits to Germany and South Korea have enriched his collaborative outlook and expanded his research frontiers 🤝. He’s also actively involved in organizing and attending seminars, gaining hands-on experience with high-performance computing and cutting-edge simulation tools ⚙️🧬.

🔹 Research Focus Area 

Dr. Kazempour’s research lies at the intersection of computational physics and nanotechnology 🔍🧪. He utilizes first-principles many-body calculations to explore electron-phonon coupling, ultrafast excitation dynamics, and quasiparticle lifetimes in nanostructures ⚛️. His work extends to investigating nonlinear optical phenomena using TD-DFT, and analyzing the effects of point and topological defects in wide bandgap semiconductors 💡🔦. Additionally, he explores strong laser-matter interactions and quantum optimal control theory in relation to quantum computation 💻🌀. His focus on fundamental and applied physics enables advancements in semiconductor design, optoelectronics, and quantum materials 🚀📡.

🔹 Awards & Honors 

🏆 Director of Nanostructured Coatings Institute, Payame Noor University
📜 Invited scientific visits to renowned institutions:

  • Fritz Haber Institute, Max Planck Society 🇩🇪

  • Ulsan National Institute of Science and Technology 🇰🇷
    🎤 Multiple international seminar participations, including ICTP and Humboldt-Kolleg
    🌟 Recognition for contributions to ultrafast dynamics and nanostructure simulation

Publication Top Notes:

1. Resonant electron–phonon coupled responses to single-shot driver: Ab initio TDDFT study of diamond

Authors: Ali Kazempour, Noejung Park
Journal: Physica B: Condensed Matter, 2025
Type: Open Access
Citations: 0
Summary:
This study employs time-dependent density functional theory (TDDFT) to investigate the resonant coupling between electrons and phonons in diamond when subjected to a single-shot laser driver. The work reveals how ultra-fast pulses influence charge density modulation and phononic excitations at femtosecond timescales, contributing to the understanding of non-equilibrium dynamics in wide bandgap materials.

2. Driven charge density modulation by spin density wave and their coexistence interplay in SmFeAsO: A first-principles study

Authors: Toktam Morshedloo, Ali Kazempour, Hamideh Shakeripour, S. Javad Hashemifar, Mojtaba Alaei
Journal: Physica B: Condensed Matter, 2024
Citations: 1
Summary:
Using density functional theory (DFT), this article explores the complex interplay between charge density waves (CDW) and spin density waves (SDW) in the iron-based superconductor SmFeAsO. The results indicate a mutual coexistence mechanism that influences the electronic structure and could play a role in the emergence of superconductivity, offering insights into magnetic and electronic modulations in high-temperature superconductors.

3. Study of optical absorption cross-section spectra and high-order harmonic generation of thymine, thymine glycol, and thymine dimer molecules

Authors: Fatemeh Mohammadtabar, Reza Rajaie Khorasani, Hossein Mohammadi-Manesh, Ali Kazempour
Journal: Journal of Molecular Modeling, 2022
Citations: 1
Summary:
This work investigates the nonlinear optical properties of thymine and its oxidized derivatives using computational modeling. The focus is on high-order harmonic generation (HHG) and optical absorption cross-sections under intense laser fields. The study contributes to the understanding of DNA damage and repair mechanisms and how molecular changes influence the nonlinear optical response in biomolecules.

Conclusion

  • Strengths: Exceptional expertise in computational physics, quantum materials, and nanostructures; proactive engagement in international scientific communities; proven leadership in research development.