Wenjie Ren | Nanocomposites | Best Researcher Award

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Dr. Wenjie Ren | Nanocomposites | Best Researcher Award

Doctor of Philosophy (Ph.D) | Henan University of Technology | China

Dr. Wenjie Ren, Ph.D., is an accomplished researcher at Henan University of Technology, China, specializing in immunological detection technologies and genetic engineering antibodies. Her research primarily focuses on developing rapid and highly sensitive biosensing systems for small molecule detection, integrating nanotechnology and immunoassay innovations to address challenges in food safety and environmental monitoring. With 1,007 citations, 67 research publications, and an h-index of 18, Dr. Wenjie Ren has established a strong scientific footprint in fields such as nanomaterial synthesis, immunochromatography, fluorescence sensing, and bioluminescent enzyme immunoassays. She has successfully led nine major research projects, including one funded by the National Natural Science Foundation of China (Youth Program) and several provincial and collaborative initiatives. Her representative works include the development of nanobody-based CuS nanoflower–Au lateral flow immunoassay strips and DNA tetrahedron fluorescence sensors for simultaneous detection of food contaminants such as aflatoxin B1 and ochratoxin A. These innovations have advanced analytical performance, sensitivity, and field applicability in food and agricultural testing. Dr. Wenjie Ren holds three authorized patents in nanobody-based and dual-signal amplification immunochromatography technologies. Her research excellence has been recognized through First and Second Prizes in the Henan Provincial Science and Technology Achievement and Progress Awards, particularly for pioneering functionalized nanocomposite biosensors. Beyond her publications and patents, she contributes as a research supervisor, fostering young scientific talent in molecular detection and biosensor design. Her interdisciplinary approach bridges immunochemistry, nanotechnology, and analytical biochemistry, positioning her as a key contributor to next-generation diagnostic sensor research and its translational applications in food safety and biomedical fields.

Profiles: Scopus | ResearchGate | Sci Profiles | Scilit | Scholar GPS

Featured Publications

  • Zhao, Y., He, B., & Ren, W. (2024). Nanobody and CuS nanoflower-Au-based lateral flow immunoassay strip to enhance the detection of aflatoxin B1. Foods, 13(12), 1845.

  • Li, Y., Li, Z., Jia, B., & Ren, W. (2024). Detection of AFB1 by immunochromatographic test strips based on double-probe signal amplification with nanobody and biotin–streptavidin system. Foods, 13(21), 3396.

  • Pang, J., Ren, W., He, B., et al. (2023). Development of a rapid gold nanoflowers immunochromatographic test strip based on the nanobody for detection of aflatoxin B1. ChemistrySelect, 8(40), e202300913.

  • Ren, W., Pang, J., Ma, R., et al. (2022). A signal on–off fluorescence sensor based on the self-assembly DNA tetrahedron for simultaneous detection of ochratoxin A and aflatoxin B1. Analytica Chimica Acta, 1198, 339566.

  • Ren, W., Xu, Y., Huang, Z., et al. (2020). Single-chain variable fragment antibody-based immunochromatographic strip for rapid detection of fumonisin B1 in maize samples. Food Chemistry, 319, 126546.

 

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.

 

Chengqiang Wang | Linear Dichroism | Best Researcher Award

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Dr. Chengqiang Wang | Linear Dichroism | Best Researcher Award

Lecturer | Hubei Key Laboratory of Micro-Nanoelectronic Materials and Devices, School of Intelligent Manufacturing, Hubei University | China

Dr. Chengqiang Wang, Lecturer at the School of Intelligent Manufacturing, Hubei University, is an accomplished researcher specializing in intelligent sensing materials and devices. His research primarily focuses on the design, optical characterization, and functional enhancement of perovskite-based nanomaterials for advanced optoelectronic and energy applications. With over 20 SCI-indexed publications, Dr. Chengqiang Wang has contributed to high-impact journals including Applied Physics Letters, Advanced Functional Materials, Angewandte Chemie International Edition, Nano Energy, and eScience—the latter featuring his work as a cover article. His total first-author SCI impact factor exceeds 85, with 214 citations and an h-index of 10 on Scopus. Dr. Chengqiang Wang’s research has yielded significant insights into electron–phonon coupling, exciton dynamics, and linear dichroism in perovskite nanostructures, pioneering developments in ultrafast transient absorption spectroscopy and optoelectronic device optimization. His innovative studies have advanced the understanding of quantum dot–liquid crystal composites and nanocomposite interactions, contributing to next-generation intelligent sensor technologies. He holds two authorized Chinese invention patents and one published application, covering novel nanomaterial fabrication and electrochemical catalyst design. Dr. Chengqiang Wang has led multiple research projects, including the Jiangsu Graduate Innovation Program, the Outstanding Doctoral Training Project, and the Hubei University Start-up Fund, and has participated in national-level grants from the National Natural Science Foundation of China (NSFC) and Fudan University. Beyond his research, Dr. Chengqiang Wang serves as a Youth Editorial Board Member for eScience (IF=42.9) and Sustainable Engineering Novit (SEn), as well as a reviewer for Materials Research and Development and related journals. A member of the Chinese Optical Engineering Society, Chinese Chemical Society, and Chinese Micro-Nano Technology Society, he has received the Outstanding Contribution Award from eScience for his exceptional editorial and scientific contributions.

Profiles: Scopus | ORCID | Google Scholar | Sci Profiles | Scilit

Featured Publications

1. M. Zhao, J. Wang, C. Wang, Y. Sun, P. Liu, X. Du, H. Pan, H. Li, H. Liang, & J. Guo. (2024). Enriched edge sites of ultrathin Ni₃S₂/NiO nanomeshes promote surface reconstruction for robust electrochemical water splitting. Nano Energy, 129, 110020.

2. T. Song, C. Q. Wang, H. Lu, X. J. Mu, B. L. Wang, J. Liu, B. Ma, J. Cao, C. X. Sheng, & H. L. Zhang. (2024). Achieving strong circularly polarized luminescence through cascade cationic insertion in lead-free hybrid metal halides. Angewandte Chemie International Edition. Advance online publication.

3. X. Zhang, L. Gao, M. Zhao, Y. Miao, Z. Wang, C. Wang, P. Liu, B. Xu, & J. Guo. (2020). Low-temperature direct synthesis of perovskite nanocrystals in water and their application in light-emitting diodes. Nanoscale, 12(11), 6522–6528.

4. C. Wang, T. Song, P. Yan, S. Hu, C. Xiang, Z. Wu, H. Li, H. Zhao, L. Han, & C. X. Sheng. (2023). Observation of electron–phonon coupling and linear dichroism in PL spectra of ultra-small CsPbBr₃ nanoparticle solution. eScience, 3(6), 100185.

5. A. Yi, M. Huangrui, & L. Qingquan. (2017). Study on the influence of the nose slenderness ratio of high-speed train on the aerodynamic noise. Chinese Journal of Theoretical and Applied Mechanics, 49(5), 985–996.

 

Noureddine Bouras | Nanobiotechnology | Excellence in Research Award

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Prof. Dr. Noureddine Bouras | Nanobiotechnology | Excellence in Research Award

Lecturer | University of Ghardaia | Algeria

Prof. Dr. Noureddine Bouras is a distinguished microbiologist whose research focuses on actinobacteria biodiversity, microbial biotechnology, and the discovery of novel bioactive compounds from Saharan ecosystems. With over 2,300+ citations, an h-index of 28, and more than 100 published documents, his scholarly work has significantly advanced microbial taxonomy, antibiotic biosynthesis, and environmental microbiology. Prof. Dr. Noureddine Bouras has contributed to the identification and classification of numerous new microbial taxa from Algerian Saharan soils, expanding the global taxonomic database with over twenty novel species and genera within Actinopolyspora, Saccharothrix, Nocardiopsis, Streptosporangium, and Actinomadura. His pioneering studies on Saccharothrix algeriensis elucidated the regulation and biosynthesis of dithiolopyrrolone antibiotics, influencing new bioprocess engineering strategies for natural product development. His research integrates microbial genomics, bioinformatics, and secondary metabolite profiling to explore bioactive molecules with antimicrobial, antifungal, and plant growth-promoting properties. He has authored influential works in high-impact journals such as Journal of Natural Products, PLOS ONE, Food and Chemical Toxicology, and Current Microbiology, and co-authored multiple scientific books on microbiology and bioresource utilization. Prof. Dr. Noureddine Bouras has led and collaborated in several national and international R&D and funding projects, notably under the Algerian PNR program, focusing on biotechnological valorization of desert microbial resources. His expertise extends to applied microbiology, biocontrol, and biosynthesis of nanoparticles for antimicrobial applications. Recognized for his extensive contributions, he serves as reviewer and editorial board member for numerous peer-reviewed journals and has presented research in global scientific forums. His innovations in microbial taxonomy, antibiotic biosynthesis, and sustainable biotechnology position him as a leading figure in North African microbial research and global actinobacterial systematics.

Profiles: Scopus | ORCID | Google Scholar | ResearchGate | AD Scientific Index

Featured Publications

1. Riba, A., Bouras, N., Mokrane, S., Mathieu, F., Lebrihi, A., & Sabaou, N. (2010). Aspergillus section Flavi and aflatoxins in Algerian wheat and derived products. Food and Chemical Toxicology, 48(10), 2772–2777.

2. Bouras, H. D., Yeddou, A. R., Bouras, N., Hellel, D., Holtz, M. D., & Sabaou, N., et al. (2017). Biosorption of Congo red dye by Aspergillus carbonarius M333 and Penicillium glabrum Pg1: Kinetics, equilibrium and thermodynamic studies. Journal of the Taiwan Institute of Chemical Engineers, 80, 915–923.

3. Bouras, H. D., Isik, Z., Arikan, E. B., Yeddou, A. R., Bouras, N., Chergui, A., Favier, L., & Sabaou, N. (2021). Biosorption characteristics of methylene blue dye by two fungal biomasses. International Journal of Environmental Studies, 78(3), 365–381.

4. Kim, Y. M., Bouras, N., Kav, N. N. V., & Strelkov, S. E. (2010). Inhibition of photosynthesis and modification of the wheat leaf proteome by Ptr ToxB: A host‐specific toxin from the fungal pathogen Pyrenophora tritici‐repentis. Proteomics, 10(16), 2911–2926.

5. Meklat, A., Bouras, N., Zitouni, A., Mathieu, F., Lebrihi, A., Schumann, P., & Sabaou, N. (2012). Actinopolyspora algeriensis sp. nov., a novel halophilic actinomycete isolated from a Saharan soil. Extremophiles, 16(5), 771–776.

 

Sunny Kumar | Nanobiotechnology | Young Scientist Award

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Mr. Sunny Kumar | Nanobiotechnology | Young Scientist Award

Researcher, CSIR-Indian Institute Of Chemical Biology, India

Mr. Sunny Kumar is an emerging researcher in cancer biology and nanomedicine, recognized for his interdisciplinary contributions that bridge molecular oncology, tumor microenvironment studies, and nanotechnology-driven therapeutics. With an h-index of 6, 11 publications, and 148 citations (as indexed in Scopus), his research reflects both productivity and impact within translational cancer science. His primary research focuses on elucidating the molecular mechanisms underlying glioma, colorectal, and breast cancer progression, emphasizing protein quality control systems such as the ubiquitin-proteasome system and their regulatory influence on oncogenic signaling. Mr. Sunny Kumar has explored novel therapeutic targets like E3 ligases (CHIP), PD-1/PD-L1 pathways, and HAUSP-MDM2 axes, offering valuable insights for cancer immunotherapy and personalized treatment strategies. In addition to mechanistic studies, Mr. Sunny Kumar integrates nanobiotechnology and drug delivery innovation, developing nanoparticle-based formulations capable of crossing the blood–brain barrier for targeted glioma therapy. His research on dual-drug nanotherapeutics and carbon nanotube-based diagnostic platforms has contributed to the advancement of precision medicine approaches for difficult-to-treat cancers. He has published extensively as first or corresponding author in high-impact journals such as Genes & Diseases (IF 9.4), BBA-Molecular Cell Research (IF 3.7), International Journal of Pharmaceutics (IF 5.2), and Journal of Medicinal Chemistry (IF 6.8). His scholarly output also includes multiple book chapters with Springer and Taylor & Francis, covering cancer proteomics, personalized therapy, and nanotherapeutics. Mr. Sunny Kumar serves as a peer reviewer for reputed journals, including BBA–Reviews on Cancer and Experimental Cell Research, further demonstrating his engagement in the scientific community. His research exhibits a robust methodological framework, integrating cell and molecular biology, bioinformatics, animal models, and nanocarrier engineering. Collectively, Mr. Sunny Kumar’s scientific endeavors underscore a commitment to next-generation cancer therapeutics, aiming to translate molecular discoveries into clinically viable nanomedicine solutions for precision oncology.

Profile: Scopus | ORCID | Google Scholar | RsearchGate

Featured Publications

1. Kumar, S., Chatterjee, M., Ghosh, P., Ganguly, K. K., Basu, M., & Ghosh, M. K. (2023). Targeting PD-1/PD-L1 in cancer immunotherapy: An effective strategy for treatment of triple-negative breast cancer (TNBC) patients. Genes & Diseases, 10(4), 1318–1350.

2. Kumar, S., Basu, M., & Ghosh, M. K. (2022). Chaperone-assisted E3 ligase CHIP: A double agent in cancer. Genes & Diseases, 9(6), 1521–1555.

3. Kumar, S., Basu, M., Ghosh, P., Ansari, A., & Ghosh, M. K. (2023). COVID‐19: Clinical status of vaccine development to date. British Journal of Clinical Pharmacology, 89(1), 114–149.

4. Kumar, S., Basu, M., Ghosh, P., Pal, U., & Ghosh, M. K. (2023). COVID-19 therapeutics: Clinical application of repurposed drugs and futuristic strategies for target-based drug discovery. Genes & Diseases, 10(4), 1402–1428.

5. Ghosh, M. K., Kumar, S., Ganguly, K. K., Ghosh, P., Tabassum, S., Basu, B., & Basu, M. (2023). COVID-19 and cancer: Insights into their association and influence on genetic and epigenetic landscape. Epigenomics, 15(4), 227–248.

 

Parvathalu Kalakonda | Nanobiotechnology | Best Researcher Award

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Assist. Prof. Dr. Parvathalu Kalakonda | Nanobiotechnology | Best Researcher Award

Assistant Professor, Government City College (A), India

Dr. Parvathalu Kalakonda is a distinguished researcher specializing in nanomaterials, polymer nanocomposites, and energy-related functional materials. His research spans the green synthesis of mono-, bi-, and tri-metal nanoparticles for antibacterial and photocatalytic applications, development of carbon- and polymer-based thermoelectric materials, and multifunctional nanocomposite scaffolds for biomedical and electronic devices. He has made significant contributions in the design and fabrication of micro-fibrous silver-coated polymeric scaffolds, flexible AgNP/PVA nanocomposite films for water purification and wound care, and carbon-based hydrogel/aerogel nanocomposites for thermal, mechanical, and thermoelectric applications. Dr. Parvathalu Kalakonda’s work employs a diverse array of methodologies, including chemical, sol-gel, and green synthesis approaches for nanoparticle fabrication, along with advanced materials characterization techniques such as XRD, SEM, TEM, AFM, UV-Vis, FTIR, Raman spectroscopy, and ellipsometry. He has expertise in thermal and mechanical analysis using DSC, MDSC, DMA, and AC calorimetry, as well as electrical characterization using four-point probe measurements and custom-developed setups for conductivity studies. His research also explores optical meta-materials, spintronics, quantum dot systems, and metal-polymer hybrid films, integrating materials science with energy and biomedical applications. Dr. Parvathalu Kalakonda has authored numerous high-impact publications, contributed book chapters, and holds patents in multifunctional nanocomposite materials and electromagnetic-based device modeling. He serves as a reviewer and editorial board member for multiple international journals, including Polymer Engineering and Science, Materials Letters, Nanomaterials and Nanotechnology, and Journal of Composites and Biodegradable Polymers. With over 360 citations, 34 publications, and an h-index of 12, his work demonstrates strong scientific impact and leadership in advanced nanomaterials research. His contributions bridge fundamental nanoscience and practical device applications, particularly in sustainable water treatment, energy harvesting, and multifunctional biomedical devices. Dr. Parvathalu Kalakonda’s interdisciplinary approach, combining synthesis, characterization, and application of advanced nanomaterials, positioning him as a leading researcher in the field of functional nanocomposites and energy materials.

Profile: Scopus | ORCID | Google Scholar | ResearchGate | Sci Profiles | Academia | Kalakondananolab

Featured Publications

  • Kalakonda, P., Kathi, R., Ligory, M. G., Dabbeta, N., Madipoju, N., Mynepally, S., … Podila, B. B. (2024). Argyreia nervosa-driven biosynthesis of Cu–Ag bimetallic nanoparticles from plant leaves extract unveils enhanced antibacterial properties. Bioprocess and Biosystems Engineering, 1–13.

  • Kalakonda, P., Mandal, P., Laxmi Mynepally, S., Bashipangu, A., Kethavath, A., Khanam, S. J., … Podila, B. B. (2024). Comparison of multi-metallic nanoparticles as alternative antibacterial agents: Understanding the role of their antibacterial properties. Journal of Inorganic and Organometallic Polymers and Materials, 1–16.

  • Parvathalu, K., Rajitha, K., Chandrashekar, B., Sathvik, K., Pranay Bhasker, K., Sreenivas, B., … Bala Bhaskar, P. (2024). Biomimetic synthesis of copper nanoparticles using Tinospora cordifolia plant leaf extract for photocatalytic activity applications. Plasmonics, 19(2), 825–834.

  • Kalakonda, P., Bashipangu, A., Mandal, P., Khanam, S. J., Banovath, M., Hasan, I., & Podila, B. B. (2024). Sustainable solutions for clean water: Green synthesized Cu–Ag bimetallic nanoparticles based nano catalyst. Materials Science and Engineering: B, 301, 117147.

  • Kalakonda, P., Thodeti, M., Ganneboina, C., Ankathi, K., Kathri, S., Begari, K., … Podila, B. B. (2024). Eco-friendly fabrication of silver nanoparticles for sustainable water purification and antibacterial synergy. Plasmonics, 1–13.

 

Kang Sun | Lignin Nanomaterials | NanoInnovator Excellence Award

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Prof. Dr. Kang Sun | Lignin Nanomaterials | NanoInnovator Excellence Award

Researcher, Chinese Academy of Forestry, China

Prof. Dr. Kang Sun is a leading researcher in the field of bio-based advanced carbon materials, recognized for his pioneering work on the theoretical design, synthesis, and industrial application of sustainable carbon nanomaterials. His research primarily focuses on biomass-derived carbon materials for energy storage, catalysis, and environmental purification. Integrating nanostructure design with data-driven process control and machine learning, he explores scalable pathways to transform biomass residues-such as lignin and cellulose—into high-performance carbon materials with enhanced electrochemical and catalytic properties. Prof. Dr. Kang Sun has made major contributions to developing lignin-derived carbon nanosheets, heterostructured catalysts, and advanced activated carbon for supercapacitors, CO₂ hydrogenation, and gas adsorption. His studies on the modulation of sp²-C domains, microstructural effects on sodium-ion battery anodes, and machine learning-guided catalyst optimization have opened new avenues for sustainable energy conversion technologies. With over 110 SCI-indexed publications in leading journals such as JACS, Angewandte Chemie, Energy & Environmental Science, Nature Communications, and Advanced Functional Materials, his work demonstrates both high scientific rigor and industrial relevance. Prof. Dr. Kang Sun’s research output is widely cited, amassing 3,780 citations, an h-index of 32, and over 200 published documents. His recent works include groundbreaking studies on Joule heating-driven carbon modulation, lignocellulose-derived energy materials, and techno-economic assessments of biomass-based hard carbon. His findings significantly influence carbon science, providing a framework for coupling material chemistry with sustainable process engineering. Beyond publications, Prof. Dr. Kang Sun has contributed to national standard formulation, authored 22 patents, and developed bio-based carbon catalysts that bridge academic discovery with industrial application. Recognized among the top 2% of global scientists, his research continues to shape the future of green energy materials and low-carbon technologies worldwide.

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

Featured Publications

  • Wu, Y., Yuan, Q., Zhao, Y., Sun, K., Sun, H., Wang, K., Hu, S., Waterhouse, G. I. N., Wu, J., Wang, Z., Jiang, J., & Fan, M. (2025). Hydroxylated boron crystal domain-modulated heterostructure carbon catalysts for efficient hydrogen peroxide generation. Journal of the American Chemical Society, 147(29), 25295–25305.

  • Wang, C., Wu, X., Sun, H., Xu, Z., Xu, C., Wang, X., Li, M., Wang, Y., Tang, Y., Jiang, J., Sun, K., & Fu, G. (2025). An asymmetric RE–O–Ru unit with bridged oxygen vacancies accelerates deprotonation during acidic water oxidation. Energy & Environmental Science, 18, 4276–4287.

  • Ning, S., Li, M., Wang, X., Zhang, D., Zhang, B., Wang, C., Sun, D., Tang, Y., Li, H., Sun, K., & Fu, G. (2023). Importing antibonding-orbital occupancy through Pd–O–Gd bridge promotes electrocatalytic oxygen reduction. Angewandte Chemie, 62(52).

  • Zhou, L., Zhang, G., Xu, C., Li, J., Liu, Y., Li, B., Wang, A., & Sun, K. (2024). Tailored regulation of graphite microcrystals via tandem catalytic carbonization for enhanced electrochemical performance of hard carbon in the low-voltage plateau. Advanced Functional Materials, 35, 2416061.

  • Wu, Y., Zhao, Y., Yuan, Q., Sun, H., Wang, A., Sun, K., Waterhouse, G. I. N., Wang, Z., Wu, J., Jiang, J., & Fan, M. (2024). Electrochemically synthesized H₂O₂ at industrial-level current densities enabled by in-situ fabricated few-layer boron nanosheets. Nature Communications, 15, 10843.

 

Assem Thabet | Nanosensors and Actuators | Best Scholar Award

Published on by Nano Technology

Prof. Dr. Assem Thabet | Nanosensors and Actuators | Best Scholar Award

Director of Studies, Research Lab MACS, University of Gabes, Tunisia

Prof. Dr. Assem Thabet is a distinguished researcher in Electrical Engineering, with a focus on Automatic Control, Industrial Computing, and Cyber–Physical Systems. His research bridges advanced control theory, system modeling, artificial intelligence, and renewable energy integration. A key area of his expertise lies in state estimation, nonlinear dynamic system control, and reciprocal state representation, where he has made notable theoretical and applied contributions. His recent book, The Reciprocal State Representation: Some Elements for the Control of Nonlinear Dynamic Systems (ISTE Group Editions, 2025), encapsulates innovative methodologies for enhancing system controllability and observer design in nonlinear environments. Prof. Dr. Assem Thabet’s research activities span multiple international collaborations across Tunisia, France, Canada, India, Italy, Algeria, and Spain, contributing to projects on AI-driven resource management, hybrid renewable energy systems, bio-inspired robotics, and smart grid optimization. His work often integrates machine learning with estimation and control theory, applying hybrid computational models to achieve system resilience under uncertain and cyber-threatened environments. With over 50 scientific publications, including 15+ papers in indexed international journals, 15+ international conference papers, and several book chapters, his scholarly influence is well-established. His studies on observer-based control, event-triggered mechanisms, and cyber-attack detection in industrial and power systems reflect his ongoing pursuit of intelligent and secure automation. Prof. Dr. Assem Thabet’s research output has garnered 125 citations across 32 documents, with an h-index of 7, reflecting the growing recognition of his scientific impact. His most recent works—such as Cyber-Attack Detection Strategy with Markovian Distribution Logic in Cyber-Physical Systems and Event-Triggered Observer-Based Control for Enhancing Resilience under Markovian Cyberattacks-demonstrate a deep engagement with contemporary challenges in resilient control and cyber-physical system security. Through his integrative and interdisciplinary approach, Prof. Dr. Assem Thabet continues to advance the frontier of intelligent control systems and sustainable automation technologies.

Profile: Scopus | ORCID | ResearchGate | Sci Profiles | IEEE Xplore | Academia | Web of Science

Featured Publications

  1. Thabet, A., Hassine, E., Gasmi, N., & Bel Haj Frej, G. (2025). Design and real-time application of explicit model-following techniques for nonlinear systems in reciprocal state space. Electronics, 14(20), 4089.

  2. Hassine, E., Thabet, A., Gasmi, N., & Bel Haj Frej, G. (2025). An event-triggered observer-based control approach for enhancing resilience of cyber–physical systems under Markovian cyberattacks. Actuators, 14(8), 412.

  3. Thabet, A., Bel Haj Frej, G., Gasmi, N., Mansouri, K., & Chauveau, E. (2022). State and output feedback control for Lipschitz nonlinear systems in reciprocal state space: Synthesis and real-time validation. Bulletin of Electrical Engineering and Informatics, 11(5), 2702–2712.

  4. Gasmi, N., Boutayeb, M., Thabet, A., Bel Haj Frej, G., & Aoun, M. (2021). Robust control of a class of nonlinear discrete-time systems: Design and experimental results on a real-time emulator. Actuators, 10(11), 303.

  5. Hassine, E., Thabet, A., Gasmi, N., Bel Haj Frej, G., & Metoui, B. (2023). Cyber-attack tolerant control of complex interconnected systems: Output feedback stabilization approach. In Proceedings of the 2023 IEEE International Workshop on Mechatronics Systems Supervision (IW_MSS 2023) (pp. 1–5). IEEE.

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.

 

Amel Boudjemaa | Nanomaterials for Energy | Women Researcher Award

Published on by Nano Technology

Dr. Amel Boudjemaa | Nanomaterials for Energy | Women Researcher Award

Researcher, Center for Scientific and Technical Research in Physicochemical Analysis (CRAPC), Algeria

Dr. Amel Boudjemaa is a prolific Algerian researcher at the Centre de Recherche Scientifique et Technique en Analyses Physico-Chimiques (CRAPC), Bou Ismail, Algeria. Her scientific contributions lie primarily in photocatalysis, nanomaterials, surface chemistry, and environmental remediation. With a Scopus h-index of 20, 1,467 citations, and 90 peer-reviewed publications, her work has significantly influenced the fields of materials chemistry and sustainable environmental technologies. Her recent research focuses on the design and optimization of advanced nanostructured photocatalysts for water purification, pollutant degradation, and hydrogen generation under visible light. Notably, she has investigated heterojunction and doped oxide-based photocatalysts—such as Co₂SnO₄/Co₃O₄/SnO₂, ZnO–CuO–Al₂O₃, and Bi/Fe-doped aluminophosphates—demonstrating enhanced degradation efficiencies for pharmaceuticals and dyes like diclofenac, ibuprofen, and methyl orange. These studies integrate experimental synthesis, photochemical characterization, and mechanistic modeling to predict by-product toxicity and reaction kinetics, emphasizing both efficiency and environmental safety. Beyond photocatalysis, Dr. Amel Boudjemaa has explored hybrid and functional nanomaterials with applications in sensing, adsorption, and energy storage. Her works on platinum(IV)-carbon sphere hybrids and tin-based non-enzymatic sensors have expanded the potential of nanomaterials for electrochemical detection and clean energy technologies. Methodologically, her research combines advanced materials synthesis, surface modification, spectroscopic and electrochemical analysis, and computational prediction tools. Her interdisciplinary approach bridges materials science, environmental engineering, and green chemistry, contributing to cleaner production and pollution mitigation strategies. Overall, Dr. Amel Boudjemaa’s body of work demonstrates a consistent pursuit of innovative, sustainable solutions for environmental contaminants, positioning her among the leading North African researchers in applied photocatalysis and nanomaterial-based remediation.

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Featured Publications

Boumaza, S., Boudjemaa, A., Bouguelia, A., Bouarab, R., & Trari, M. (2010). Visible light induced hydrogen evolution on new hetero-system ZnFe₂O₄/SrTiO₃. Applied Energy, 87(7), 2230–2236.

Boudjemaa, A., Boumaza, S., Trari, M., Bouarab, R., & Bouguelia, A. (2009). Physical and photo-electrochemical characterizations of α-Fe₂O₃: Application for hydrogen production. International Journal of Hydrogen Energy, 34(10), 4268–4274.

Chezeau, B., Boudriche, L., Vial, C., & Boudjemaa, A. (2020). Treatment of dairy wastewater by electrocoagulation process: Advantages of combined iron/aluminum electrodes. Separation Science and Technology, 55(14), 2510–2527.

Boumaza, S., Boudjemaa, A., Omeiri, S., Bouarab, R., Bouguelia, A., & Trari, M. (2010). Physical and photoelectrochemical characterizations of hematite α-Fe₂O₃: Application to photocatalytic oxygen evolution. Solar Energy, 84(4), 715–721.

Boudjemaa, A., Bouarab, R., Saadi, S., Bouguelia, A., & Trari, M. (2009). Photoelectrochemical H₂-generation over spinel FeCr₂O₄ in X²⁻ solutions (X²⁻ = S²⁻ and SO₃²⁻). Applied Energy, 86(7–8), 1080–1086.