Njemuwa Nwaji | Qualitative Research | Research Excellence Award

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Assist. Prof. Dr. Njemuwa Nwaji | Qualitative Research | Research Excellence Award

Institute of Fundamental Technological Research, Polish Academy of Science | Poland

Assist. Prof. Dr. Nwaji Njemuwa Njoku is a materials chemist and nanotechnology researcher with extensive international academic and research experience across Africa, Europe, and Asia. He earned a Ph.D. in Chemistry from Rhodes University, South Africa, following an M.Sc. in Organic Chemistry from the University of Central Lancashire, United Kingdom, and a B.Tech. in Industrial Chemistry from the Federal University of Technology, Owerri. He is currently an Assistant Professor at the Institute of Fundamental Technological Research, Polish Academy of Sciences, where he contributes to doctoral-level teaching and advanced research. Previously, he held research and academic positions at Chungnam National University (South Korea), South China Normal University (China), and Alex Ekwueme Federal University (Nigeria). His research focuses on nanotechnology for energy storage and conversion, including advanced nanomaterial synthesis, photo- and electrocatalysis for hydrogen production, high-performance supercapacitor electrodes, and biocompatible nanomaterials for biomedical applications. He has supervised undergraduate and postgraduate research projects and mentored international graduate students. His scholarly output is reflected in a strong citation record and an H-index of 21. He has received competitive international funding, including serving as Principal Investigator on a major National Research Foundation of South Korea grant, underscoring his contributions to sustainable energy and functional nanomaterials research.

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Featured Publications

Chong-Qing Wan | Data Quality Enhancement | Best Researcher Award

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Prof. Chong-Qing Wan | Data Quality Enhancement | Best Researcher Award

Capital Normal University | China

Prof. Chong-Qing Wan is a distinguished professor in the Department of Chemistry at Capital Normal University, Beijing, recognized for his extensive contributions to functional coordination chemistry and framework materials, with a research record comprising 83 scientific documents, an h-index of 24, and 1,987 citations from 1,717 documents. He earned a BA in chemistry from Xinyang Normal University, an MS from Nankai University with research on coordination complexes, and later completed his PhD under Prof. Thomas C. W. Mak at The Chinese University of Hong Kong. His work spans the synthesis, characterization, and application of metal–organic frameworks (MOFs), covalent–organic frameworks (COFs), ionic-liquid-based hybrids, and energy-related materials. He has published impactful studies in Nature Communications, Angewandte Chemie, and Chemistry of Materials, contributing to advances in MOF/COF meltability, glass formation, proton-conductive crystalline ionic liquids, and atomically precise nanoclusters. His research interests include functional coordination complexes, energy-storage materials, photocatalysis, and phase-transition mechanisms in porous frameworks. Throughout his academic career, he has been recognized for high-impact publications and sustained contributions to materials chemistry. Continuing to advance the field through innovative synthesis strategies and collaborative research, he remains a leading figure in framework-based materials and functional molecular systems.

Profiles : Scopus | Orcid

Featured Publications

Xue, W. L., Li, G. Q., Chen, H., Han, Y. C., Feng, L., Gu, X. L., Hu, S. Y., Deng, Y. H., Tan, L., Dove, M. T., Li, W., Zhang, J., Dong, H., Chen, Z., Deng, W. H., Xu, G., & Wan, C.-Q. (2024). Melt-quenched glass formation of a family of metal–carboxylate frameworks. Nature Communications, 15, 2040.*

Gu, X. L., Zhao, L., Sun, J., Cui, X. K., Li, G. Q., Hu, S. Y., Deng, Y. H., Li, Z., Li, K., Wang, H., & Wan, C.-Q. (2024). Synthesis and properties of zwitterionic covalent organic framework (COF): The meltability strategy and processability. Chemistry of Materials, 36, 2674–2684.*

Xue, W.-L., Deng, W.-H., Chen, H., Liu, R.-H., Taylor, J. M., Li, Y.-K., Wang, L., Deng, Y.-H., Li, W.-H., Wen, Y.-Y., Wang, G.-E., Wan, C.-Q., & Xu, G. (2021). MOF-directed synthesis of crystalline ionic liquids with enhanced proton conduction. Angewandte Chemie International Edition, 60, 1290–1297.

Qin, Z., Sharma, S., Wan, C.-Q., Malola, S., Xu, W.-W., Häkkinen, H., & Li, G. (2021). A homoleptic alkynyl-ligated [Au₁₃Ag₁₆L₂₄]³⁻ cluster as a catalytically active eight-electron system. Angewandte Chemie International Edition, 60, 970–975.*

Qin, Z., Zhang, J., Wan, C.-Q., Liu, S., Abroshan, H., Jin, R., & Li, G. (2020). Atomically precise nanoclusters with reversible isomeric transformation for rotary nanomotors. Nature Communications, 11, 6019.*

Jiabao Li | Engineering | Research Excellence Award

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Mr. Jiabao Li | Engineering | Research Excellence Award

Yangzhou University | China

Mr. Jiabao Li is a materials scientist and electrochemical energy researcher specializing in sodium-ion batteries and capacitive deionization, with particular focus on electrode and electrolyte design for extreme temperature environments. He earned his bachelor’s and master’s degrees in applied chemistry from Anhui Agricultural University, followed by a Ph.D. in materials and optoelectronics from East China Normal University, including a joint research period at the Georgia Institute of Technology. Since completing his doctoral work, he has served as a lecturer and researcher, leading multiple competitive research projects in materials innovation and energy-storage systems. His work integrates experimental synthesis with computational tools such as DFT modeling and molecular dynamics simulations to advance high-performance sodium-ion storage materials. He has published 98 scientific documents, accumulating 5,410 citations across 4,235 referencing documents, with an h-index of 40, reflecting significant global impact in the fields of battery chemistry and electrochemical engineering. His awards include national and institutional scholarships that recognize excellence in scientific research and academic achievement. Overall, his career demonstrates sustained contributions to next-generation energy-storage technologies and the advancement of robust sodium-ion systems for low-temperature and high-efficiency applications.

Profile : Scopus

Featured Publications

Unveiling the neglected role of oxygen doping in nitrogen-doped carbon for enhanced capacitive deionization performance. Nature Communications, 2025.

Rapidly evaluating electrochemical performance of transition metal disulfides for lithium-ion batteries using machine learning classifier. Chemical Engineering Journal, 2025.

Ionic conductor-armored Li₃V₂(PO₄)₃: a robust electrode for lithium capture via capacitive desalination. Chemical Communications, 2025.

Anion screening in ether-based electrolytes for boosted sodium storage at low temperature. Energy Storage Materials, 2025.

Coordination-tuned Na₃V₂(PO₄)₃ cathodes for low-temperature sodium-ion batteries. Chemical Communications, 2025.

 

Vilma Petkova | Qualitative Research | Best Researcher Award

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Prof. Vilma Petkova | Qualitative Research | Best Researcher Award

Institute of Mineralogy and Crystallography “Acad. Ivan Kostov”, Bulgarian Academy of Sciences | Bulgaria

Prof. Vilma Petkova is an eminent chemist-engineer and researcher specializing in inorganic materials science, crystallography, thermal analysis, and environmentally clean technologies. She holds a Ph.D. in Chemical Technology and Metallurgy and has over three decades of academic and research experience, serving in positions ranging from Assistant Professor to full Professor at the Institute of Mineralogy and Crystallography, Bulgarian Academy of Sciences, and New Bulgarian University. Her research spans inorganic substances, nanomaterials, cement and construction materials, fertilizers, solid-phase kinetics, thermal and X-ray analysis, spectroscopy, and eco-friendly materials. Prof. Petkova has supervised numerous bachelor, master, and Ph.D. students, actively participated in over 130 national and international conferences, and contributed to more than 193 publications, including 89 indexed in IF/SJR journals, accumulating 904 citations across 744 documents with an h-index of 18. She has led and participated in national and international research projects, served on scientific councils, editorial boards, and accreditation panels, and received recognition for her leadership in thermal analysis and materials science. Her expertise integrates material characterization, environmental chemistry, biotechnology, and sustainable development. Prof. Petkova continues to advance research, mentor emerging scientists, and contribute to global knowledge in material science and chemistry, promoting innovations that balance technological progress with environmental sustainability.

Profiles : Scopus | Orcid | Google Scholar

Featured Publications

Petkova, V., Mihaylova, K., Serafimova, E., Titorenkova, R., Tsvetanova, L., & Trikkel, A. (2025). “Impact of High Energy Milling and Mineral Additives on a Carbonate–Quartz–Apatite System for Ecological Applications.” Materials.

Petkova, V., Mihaylova, K., Kaljuvee, T., & Piroeva, I. (2025). “Induced structural changes within a natural apatite-calcite system via short-time mechanochemical activation.” Materials Chemistry and Physics.

Petkova, V., Stoyanov, V., Mihaylova, K., & Kostova, B. (2025). “Impact of pozzolanic and inert powders on the microstructure and thermal chemistry of cement mortars.” Ceramics International.

Stoyanov, V., Petkova, V., Mihaylova, K., & Shopska, M. (2024). “A Study of the Influence of Thermoactivated Natural Zeolite on the Hydration of White Cement Mortars.” Materials.

Serafimova, E., & Petkova, V. (2022). “BTEX exposure in indoor air in schools in Bulgaria.” IOP Conference Series: Materials Science and Engineering.

Larisa Mezentseva | Real-world Case Studies | Best Scholar Award

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Dr. Larisa Mezentseva | Real-world Case Studies | Best Scholar Award

National Research Centre Kurchatov Institute | Russia

Dr. Larisa P. Mezentseva is a distinguished materials chemist and Leading Researcher at the I.V. Grebenshchikov Institute of Silicate Chemistry (Branch of NRC “Kurchatov Institute,” Russia), with over five decades of expertise in inorganic and materials chemistry. She earned her Ph.D. in Chemistry from the Institute of Silicate Chemistry of the Russian Academy of Sciences, focusing on the phase diagrams of lanthanide–phosphate systems. Her research primarily centers on the synthesis, crystal chemistry, and functional properties of rare-earth phosphates, aluminates, and nanostructured oxide ceramics. She has made significant contributions to sol-gel synthesis methods, phase equilibria studies, and the development of advanced ceramic materials for high-temperature and nuclear applications. Dr. Mezentseva has published more than 49 scientific papers, accumulated over 522 citations, and holds an h-index of 13 (Scopus). Her work has appeared in leading international journals such as Glass Physics and Chemistry, Journal of Nuclear Materials, and Russian Journal of Inorganic Chemistry. She has also contributed to patents and collaborative projects advancing the design and application of functional oxide materials. Through her extensive scientific output and mentorship, Dr. Mezentseva has played a vital role in strengthening global understanding of rare-earth ceramics and functional materials.

Profiles : Orcid | Scopus

Featured Publications

Mezentseva, L. (2022). “Ceramic Composites Based on Lanthanum Orthophosphate and Alumina: Preparation and Properties” in Glass Physics and Chemistry.

Mezentseva, L. (2021). “Ceramic Composite Matrices Based on the LaPO4–ZrO2 System: Preparation and Properties” in Glass Physics and Chemistry.

Mezentseva, L. (2021). “Ceramic Composites Based on Nanosized Lanthanum Orthophosphate and Their Properties” in Glass Physics and Chemistry.

Mezentseva, L.P.; Osipov, A.V.; Ugolkov, V.L.; Akatov, A.A.; Doil’nitsyn, V.A. (2019). “Physicochemical Properties of Ceramics Based on a LaPO4–DyPO4 System” in Glass Physics and Chemistry.

Mezentseva, L.; Osipov, A.; Ugolkov, V.; Kruchinina, I.; Maslennikova, T.; Koptelova, L. (2019). “Sol–gel Synthesis of Precursors and Preparation of Ceramic Composites Based on LaPO4 with Y2O3 and ZrO2 Additions” in Journal of Sol-Gel Science and Technology.

Abdulrazzaq Hammal | Industrial Chemistry | Best Researcher Award

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Dr. Abdulrazzaq Hammal | Industrial Chemistry | Best Researcher Award

Faculty member at the University of Aleppo | Syria

Dr. Abdulrazzaq Hammal is a distinguished faculty member at the University of Aleppo, Faculty of Electrical Engineering, Department of Basic Sciences (Industrial Chemistry), specializing in industrial chemistry, nanochemistry, building materials, natural raw materials, and water treatment. He earned his Bachelor’s degree in Applied Chemistry (2008), Master’s in Applied Chemistry with a focus on Inorganic Industries (2012), and PhD in Applied Chemistry – Inorganic Industries (2017), all from the University of Aleppo. With more than 40 publications in international and regional journals, his research has advanced innovative solutions in ceramic membranes, nanomaterials, water purification, and biomedical applications, garnering significant academic impact with an h-index of 3, over 18 citations, and more than 7 documents indexed in Scopus and Google Scholar. Dr. Hammal has contributed to international conferences across Syria, Iraq, and Malaysia, also serving as Chairman of the Organizing Committee for the Fourth Chemistry Conference at the University of Aleppo. His innovative research has been recognized with multiple honors, including the Best Invention Award at Al-Basil Exhibition (2018), the Best Research Award from Aleppo University (2018), and medals from the ARID platform (2020–2022). Dedicated to mentoring, organizing workshops, and leading the Syrian Scientific Olympiad in Chemistry, Dr. Hammal continues to contribute impactful research toward sustainable industrial and environmental solutions.

Profiles : Scopus | Orcid

Featured Publications

Hammal, A. (2025). Preparation of geopolymer membranes using clay and some industrial wastes to remove the organic load of pharmaceutical wastewater. BMC Research Notes.

Hammal, A. (2024). Preparation of nano-silica and nano-silicone. Basic and Applied Sciences – Scientific Journal of King Faisal University.

Hammal, A., Al-Hamed Al-Duihi, H., & Alchab, L. (2024). Preparation of nano hydroxyapatite loaded with Syrian Inula extract against dental caries. Materials Chemistry and Physics.

Hammal, A., & Sulaiman, A. (2024). Isolating pure silica from Syrian clay for bioglass manufacturing. Kufa Journal of Engineering.

Neha Choudhary | Environmental Data Analysis | Women Researcher Award

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Dr. Neha Choudhary | Environmental Data Analysis | Women Researcher Award

Sorbonne Université | France

Dr. Neha Choudhary is a postdoctoral researcher at Institut Jean Le Rond d’Alembert, Sorbonne Université, France, with expertise in materials and inorganic chemistry, particularly in the development of nanomaterials and single-atom catalysts. Her work focuses on designing sustainable catalytic systems for environmentally benign organic transformations and CO₂ conversion into valuable chemicals. With a strong foundation in catalysis and nanotechnology, Dr. Choudhary has contributed significantly to advancing green chemistry and renewable energy solutions through innovative research and international collaborations.

Professional Profile

Google Scholar

Education

Dr. Choudhary earned her Ph.D. in Chemistry from the Indian Institute of Technology Indore, where she conducted extensive research on the design and synthesis of bimetallic catalysts for environmentally friendly organic transformations. She also holds a Master of Science in Chemistry from the School of Chemical Sciences, DAVV, Indore, and a Bachelor of Science with a focus on Physics, Chemistry, and Mathematics from Govt. Holkar Science College, Indore. Her strong academic background is further supported by her qualification in competitive national-level examinations, which strengthened her expertise in catalysis and materials chemistry.

Experience

Dr. Choudhary has extensive experience in academia and research, beginning as a guest faculty member in chemistry at Govt. Polytechnic College, Dewas, where she also taught environmental chemistry and mentored students. She further advanced her research expertise as a Research Associate under a DAE-BRNS scheme at IIT Indore, focusing on catalytic applications of nanocatalysts derived from single-source molecular precursors. Currently, as a Postdoctoral Fellow at Sorbonne Université under the PEPR PowerCO₂ Scheme, she designs and synthesizes three-dimensional structured materials and single-atom catalysts for the conversion of CO₂ into methane and methanol. Her work integrates advanced catalytic materials with renewable energy applications, contributing to global sustainability goals.

Research Interest

Her research interests lie in heterogeneous catalysis, nanomaterials, single-atom catalysts, CO₂ hydrogenation, biomass conversion, and sustainable energy solutions. She specializes in the development of bimetallic and single-atom catalysts for environmentally benign transformations, with a strong emphasis on recyclability, robustness, and cost-effectiveness. Dr. Choudhary’s research also explores electrochemical performance of nanostructured materials for energy storage and CO₂ fixation, bridging the gap between catalysis, green chemistry, and sustainable development.

Awards and Achievements

Dr. Choudhary has actively contributed to numerous international and national conferences, including the European Materials Research Society Fall Meeting, International Conference on Environmental Catalysis, and ICANN conferences. She has presented her research through oral talks and posters in globally recognized events such as the Commonwealth Chemistry Poster Competition and RSC Twitter Poster Conference. She has completed several certified courses from reputed international institutions on nanotechnology, molecular spectroscopy, and nanosensors. Her academic journey is marked by active participation in workshops, webinars, and research symposia focusing on catalysis, renewable energy, and sustainable chemistry. Beyond her academic achievements, she holds accolades in extracurricular activities, including martial arts and cultural events, demonstrating a well-rounded professional profile.

Publications

Chandra, P., Choudhary, N., Lahiri, G.K., Maiti, D., Mobin, S.M. (2021). “Copper Mediated Chemo‐ and Stereoselective Cyanation Reactions.” Asian Journal of Organic Chemistry, 10(8), 1897–1937.

Singh, A., Choudhary, N., Mobin, S.M., Mathur, P. (2021). “Cubane Ru₄(CO)₈ Cluster Containing 4 Pyridine-Methanol Ligands as a Highly Efficient Photoelectrocatalyst for Oxygen Evolution Reaction from Water.” Journal of Organometallic Chemistry, 940, 121769.

Ghosh, T., Choudhary, N., Mobin, S.M. (2020). “Design and Synthesis of Silver Decorated Fe₃O₄@Fe Doped CeO₂ Core‐Shell Ternary Composite as Highly Efficient Nanocatalyst for Selective Oxidation of ….” ChemistrySelect, 5(31), 9601–9606.

Choudhary, N., Parsai, P., Shaikh, M.M. (2024). “3d Transition Metal-Based Single-Atom Catalyst as an Emerging Field for Environmentally Benign Organic Transformation Reactions.” Molecular Catalysis, 565, 114360.

Choudhary, N., Hussain, N., Mobin, S.M. (2023). “Insights on Effect of Different Electrolytes on Electrochemical Performance of CoNi Nanoflower‐Based Supercapacitors.” Energy Technology, 11(10), 2300521.

Choudhary, N., Srivastava, N., Annadata, H.V., Ghosh, B., Da Costa, P. (2025). “The Dual‐Active‐Site Catalysts Containing Atomically Dispersed Pr³⁺ with Ni/CeO₂ for CO₂ Hydrogenation to Methane.” Small, 2504707.

Conclusion

Dr. Neha Choudhary exemplifies a dynamic researcher with a deep commitment to advancing the field of materials and inorganic chemistry through innovative catalysis and nanotechnology. Her contributions toward sustainable CO₂ conversion and green chemical processes align with global environmental objectives. With an extensive publication record in high-impact journals and a strong network of international collaborations, she continues to pioneer advancements in catalytic science for cleaner and greener chemical processes. Her vision includes fostering innovation in renewable energy catalysis, mentoring emerging researchers, and bridging the gap between academic research and industrial application to promote a more sustainable future.

Rubesh Ashok Kumar s | Science and Humanities Research | Best Researcher Award

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Dr. Rubesh Ashok Kumar s | Science and Humanities Research | Best Researcher Award

Chennai institute of technology | India

Dr. Rubesh Ashok Kumar is a dynamic and passionate research scholar in the field of materials science, currently pursuing his Ph.D. at Aarupadai Veedu Institute of Technology (AVIT), Chennai, under Vinayaka Mission’s Research Foundation (VMRF). With a strong foundation in chemistry and over four years of hands-on experience in academic and applied research, he has made notable contributions to the development of nanomaterials, particularly focusing on MXene-based semiconductor nanocomposites for environmental remediation. His dedication to scientific inquiry is reflected in his extensive publication record, collaborative projects, and consistent participation in national and international conferences. Dr. Rubesh is known for his methodical approach to experimental chemistry and his commitment to solving real-world environmental issues through innovative photocatalytic technologies.

Professional Profile

ORCID

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Education

Dr. Rubesh Ashok Kumar began his academic journey with a Bachelor’s degree in Chemistry from The American College, followed by a Master’s degree in Chemistry from NMSSVN College. These formative years laid the groundwork for his deep interest in materials chemistry and nanotechnology. His academic training emphasized core chemical principles, analytical techniques, and experimental design, which he later expanded upon during his postgraduate project on selective ion detection using hydrazone units. His current doctoral research at AVIT focuses on the synthesis and characterization of semiconductor metal oxide-incorporated MXene nanomaterials, targeting efficient photocatalytic applications for environmental cleanup. This research has allowed him to explore advanced synthesis methods such as hydrothermal and co-precipitation techniques, contributing significantly to his academic and professional growth.

Experience

Dr. Rubesh’s professional journey reflects a seamless integration of academic research and technical expertise. He began his career as a Technical Analyst at SPI Global, where he worked on chemistry-related content and analysis. He later joined SRM Institute of Science and Technology (SRM-IST), Chennai, as a researcher, focusing on graphene-based polymer nanocomposites for energy and environmental applications. Since November 2021, he has been working as a Ph.D. scholar at AVIT, where he has been instrumental in leading projects related to MXene nanocomposites for wastewater treatment. His collaborative nature and research aptitude have led to successful partnerships with renowned institutions and scientists from Taiwan, South Korea, and India. He has also engaged in teaching undergraduate courses, offering lab instruction in engineering chemistry and environmental science, further extending his influence as a mentor and educator.

Research Interest

Dr. Rubesh’s research interests lie at the intersection of nanotechnology and environmental science. His core focus is the development of MXene-based semiconductor nanocomposites for advanced oxidation processes (AOP) to treat dye pollutants, antibiotics, and pharmaceutical waste in wastewater. He specializes in synthesizing various metal oxide nanomaterials using hydrothermal and co-precipitation techniques, investigating their structural, optical, and photocatalytic properties. His work involves rigorous studies on photocatalytic degradation under visible and sunlight irradiation using annular photo reactors, and includes electrochemical analysis and thin film coatings. In addition, he has explored reaction kinetics, reusability studies, and catalyst optimization to enhance the real-time efficiency of wastewater remediation processes. His skillset extends to multiple analytical techniques, such as FTIR, UV-Vis spectroscopy, AFM, and COD analysis, positioning him as a well-rounded and highly capable materials chemist.

Awards and Recognitions

Dr. Rubesh has received several accolades for his outstanding research contributions. He secured the first prize at the International Conference on Hybrid Solar Cell Technology (ICSCT 2023) for his oral presentation on photocatalytic degradation using MXene-based materials. His work was further recognized with the third prize during the University Research Day 2024 organized by VMRF for his innovative presentation on sunlight-assisted degradation of pollutants. These achievements highlight not only his academic excellence but also his ability to communicate complex scientific findings effectively. Moreover, he has been an active participant in numerous workshops, training programs, and international seminars focused on nanomaterials and environmental technology, demonstrating his continuous commitment to professional development.

Publications

Impact of WO₃:CeO₂@MXene/g-C₃N₄ nano disk on sunlight-driven photocatalytic removal of fluoroquinolone antibiotic and high-performance supercapacitor application

Authors: Rubesh Ashok Kumar Selvakumar; Vasvini Mary Devaraj; Rachel Angeline Lenin; Nagarani Sandran; Jih-Hsing Chang; Suganya Josephine Gali Anthoni
Journal: Carbon Letters
Year: 2025

An efficient rare earth metal oxide-supported MXene/g-C₃N₄ photocatalyst for removing organic dye from wastewater

Authors: D. Vasvini Mary; S. Rubesh Ashok Kumar; G.A. Suganya Josephine
Journal: Journal of the Indian Chemical Society
Year: 2025

Nano Janue-like N-doped ZnO bundles as efficient photocatalysis for the removal of endocrine disruptor under visible-light irradiation

Authors: Suganya Josephine Gali Anthoni; Rubesh Ashok Kumar Selva Kumar; Vasvini Mary Devaraj; Prathap Kumar Mani; Sivasamy Arumugam
Journal: Pure and Applied Chemistry
Year: 2025

Construction of coral reef-like transition/rare earth metal oxide-supported g-C₃N₄-based nanocomposite: A new approach for enhanced visible light-assisted photocatalytic removal of orange G dye

Authors: D. Vasvini Mary; S. Rubesh Ashok Kumar; Jennifer G. Joseph; B. Dhanalakshmi; G.A. Suganya Josephine
Journal: Applied Catalysis O: Open
Year: 2024

Graphene/GO/rGO based nanocomposites: Emerging energy and environmental application–review

Authors: S. Rubesh Ashok Kumar; D. Vasvini Mary; G.A. Suganya Josephine; Mohamed A. Riswan Ahamed
Journal: Hybrid Advances
Year: 2024

Hydrothermally synthesized WO₃:CeO₂ supported g-C₃N₄ nanolayers for rapid photocatalytic degradation of azo dye under natural sunlight

Authors: S. Rubesh Ashok Kumar; D. Vasvini Mary; G.A. Suganya Josephine; A. Sivasamy
Journal: Inorganic Chemistry Communications
Year: 2024

Conclusion

Dr. Rubesh Ashok Kumar exemplifies a new generation of researchers dedicated to addressing environmental challenges through scientific innovation. With a solid academic background, diverse research experience, and a clear focus on sustainable nanomaterials, he stands out as a promising scientist in the field of photocatalysis and wastewater treatment. His collaborative projects, international exposure, and consistent contributions to high-impact journals underscore his potential to make long-lasting contributions to environmental nanotechnology. As he continues to advance in his academic journey, Dr. Rubesh remains committed to producing impactful research that bridges material science with environmental sustainability, contributing meaningfully to global scientific progress.