Deepak Mohite | Materials Chemistry | Green Chemistry Award

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Mr. Deepak Mohite | Materials Chemistry | Green Chemistry Award

K.H. College Gargoti | India

Mr. Deepak Bandopant Mohite is an emerging material chemistry researcher whose work focuses on developing innovative and sustainable catalytic materials with strong relevance to green chemistry. He holds an M.Sc. in Organic Chemistry and has qualified for prestigious national examinations including CSIR-NET-JRF, SET, and GATE, reflecting his solid academic foundation. Currently, he is serving as an Assistant Professor of Chemistry at Karmaveer Hire Arts, Science, Commerce and Education College, Gargoti, affiliated with Shivaji University, Kolhapur, where he has gained two years of full-time teaching and research experience. Alongside his academic role, he is pursuing a Ph.D. at Shivaji University, Kolhapur. His doctoral research “Catalytic studies of titania-coated magnetic mixed metal oxide with interlayer alumina, zirconia, and silica” involves the design, synthesis, and characterization of advanced heterogeneous catalysts that are efficient, reusable, and environmentally benign. Mr. Mohite’s work aims to reduce the ecological footprint of chemical transformations by developing catalysts that offer high activity, selectivity, and recyclability while minimizing waste and energy consumption. His research integrates principles of green chemistry with material innovation, focusing on magnetic mixed metal oxides that can be easily recovered and reused, thereby supporting cleaner industrial processes. He has published his findings in the Journal of Molecular Structure (SCI/Scopus indexed), demonstrating the scientific merit and relevance of his work. Additionally, he holds a granted German patent, reflecting his capability to translate research ideas into applicable technological solutions. Through his contributions, Mr. Mohite is advancing sustainable material development and environmentally responsible catalysis with potential impact across chemical and industrial sectors.

Profile : Scopus

Featured Publication

Mohite, D. B., Pandhare, A. B., Chavan, A. S., Kadam, M. R., Nikam, P. N., Junghare, N. V., Ayyar, M., Rajendran, S., Khan, M. A., Delekar, S. D., Patil, R. P., Santhamoorthy, M., & Santhoshkumar, S. (2026). CoFe₂O₄–Al₂O₃–TiO₂ nanocatalyst: Magnetically retrievable platform for medicinal precursors. Journal of Molecular Structure, 1352(Part 2), 144521.

Abdel-Nasser Alaghaz | Inorganic Chemistry | Research Excellence Award

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Prof. Abdel-Nasser Alaghaz | Inorganic Chemistry | Research Excellence Award

Jazan University | Saudi Arabia

Dr. Abdel-Nasser M. A. Alaghaz is a distinguished Egyptian chemist and Professor of Inorganic and Analytical Chemistry at Al-Azhar University, with over two decades of dedicated academic and research experience. His research primarily focuses on coordination chemistry and phosphorus-containing ligands, with a particular emphasis on cyclodiphosph(V)azane derivatives and related compounds. Dr. Alaghaz has made significant contributions to the synthesis, characterization, and biological evaluation of transition metal complexes, including Co(II), Ni(II), Cu(II), and Pd(II). His work integrates detailed physicochemical analyses, such as thermal stability, electrical conductivity, and spectral characterization (IR, UV-Vis, NMR), to explore structure–property relationships. Many of his studies have investigated the correlation between molecular structure and biological activity, highlighting potential pharmaceutical applications and advancing the development of functional materials. Over the years, he has authored numerous high-impact publications in peer-reviewed journals, showcasing novel synthetic strategies and elucidating ligand–metal interactions. Beyond research, Dr. Alaghaz is a respected educator and mentor, guiding graduate and doctoral students, shaping curricula, and fostering scientific inquiry. His work bridges fundamental inorganic chemistry and applied bioinorganic research, influencing both academic and industrial practices. By combining theoretical insights with practical innovation, Dr. Alaghaz has significantly enriched the fields of inorganic synthesis, materials chemistry, and bioinorganic applications. His groundbreaking contributions and unwavering dedication make him a prominent figure in chemistry, inspiring future generations of scientists in Egypt and internationally.

Profiles : Scopus | ORCID | Google Scholar

Featured Publications

1. Siddiq, H. A., Alkhathami, N. D., Ageeli, A. A., Mousa, I., Alenazy, D. M., Alatawi, N. M., & Alaghaz, A.-N. M. A. (2025). Synthesis and quantum chemical calculations of nano‐sized metal (III/II) complexes of furan‐based Schiff base for promising therapeutic studies: Interaction with biomolecules, antioxidant activity, in vitro cytotoxicity, apoptotic activity, and cell cycle analysis. Applied Organometallic Chemistry.

2. Alenazy, D. M., Siddiq, H. A., Alatawi, N. M., Ageeli, A. A., Alkhathami, N. D., Mousa, I., & Alaghaz, A.-N. M. A. (2025). Synthesis, DFT, spectral characterization, cell cycle, apoptosis, cytotoxicity, DNA binding/cleavage, molecular docking, and antimicrobial insights of nano‐sized Pd (II) and Cu (II) complexes with benzothiazole‐appended ligand. Applied Organometallic Chemistry.

3. Alaghaz, A.-N. M. A., Hakami, O., Alamri, A. A., Amri, N., Souadi, G., & Aldulmani, S. A. (2025). Cell cycle arrest, apoptosis assay, cytotoxicity, molecular docking, DNA binding/cleavage, and biological evaluation of Pt(II), Ni(II), Pd(II), and Cu(II) nano‐sized complexes of 2‐(6-fluorobenzo[d]thiazol‐2‐yl)phenol: Design, synthesis, and spectral approach. Applied Organometallic Chemistry.

4. Mousa, I., Madkhali, M. M. M., Siddiq, H. A., Alaghaz, A.-N. M. A., Rezk, G. N., & El-Bindary, A. A. (2025). Synthesis, characterization, DFT calculations, and pharmacological activity of azo dye ligand and its Cu(II) complex comprising nitrogen and oxygen donor atoms. Applied Organometallic Chemistry.

5. Alkhathami, N. D., Alenazy, D. M., Mousa, I., Alatawi, N. M., Siddiq, H. A., Ageeli, A. A., & Alaghaz, A.-N. M. A. (2025). Design, synthesis, DFT, and biological evaluation of nano‐sized Pt(II) and Cu(II) complexes of 2‐(benzo[d]oxazol‐2‐yl)phenylphosphoramidic dichloride: Spectral analysis, cell cycle arrest, apoptosis assay, cytotoxicity, and DNA binding/cleavage. Applied Organometallic Chemistry.

Hee-Tae Jung | Materials Chemistry | Best Researcher Award

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Prof. Hee-Tae Jung | Materials Chemistry | Best Researcher Award

Korea Advanced Institute of Science and Technology | South Korea

Professor Hee-Tae Jung is a leading global scientist in chemical and biomolecular engineering whose research centers on developing advanced functional nanomaterials and nanostructures to address critical climate-related and environmental challenges. As Chair Professor at KAIST and Director of multiple international research centers including the Saudi Aramco-KAIST CO₂ Management Center and the KAIST-UCB-VNU Global Climate Change Research Center, he leads multidisciplinary teams focused on creating transformative technologies for greenhouse gas mitigation, sustainable energy production, and high-performance sensor systems. His research group, OOEM, pioneers both top-down and bottom-up nanofabrication approaches, introducing innovations such as secondary sputtering, soft-lithography, supramolecular self-assembly, and advanced nano-patterning. These techniques enable precise control of material architectures to achieve unprecedented performance in catalytic, sensing, and energy-conversion applications. A central aim of his work is to bridge fundamental nanoscience with industrial-scale practical devices, accelerating translation of high-impact research into real-world environmental solutions. Professor Jung’s contributions span CO₂ reduction systems, bifunctional water-splitting catalysts, MXene-based gas sensors with ultrahigh signal-to-noise ratios, deep-learning-assisted chemical sensing, high-density nanoparticle generation via carbothermal shock, and large-area supramolecular alignment. His research has been published in top-tier journals including Nature Electronics, Science Advances, Advanced Materials, Nature Nanotechnology, and ACS Nano. With an exemplary record of leadership serving as President of the Korean Environmental Science Society and Associate Editor for several international journals and numerous prestigious awards, Professor Jung is recognized as one of the most influential scientists in nanomaterials, CO₂ management, and climate-centric engineering innovation. His work continues to shape the future of sustainable materials and technologies.

Profiles : ScopusGoogle Scholar

Featured Publications

  • Continuous biochemical profiling of the gastrointestinal tract using a multiparametric smart capsule. (2025). Nature Electronics, 8, 844.

  • Continuous flow-reactor with superior production rate and stability for CO₂ reduction using semiconductor photocatalysts. (2023). Energy & Environmental Science, 16, 2689.

  • Exploring optimal water splitting bifunctional alloy catalyst by Pareto active learning. (2023). Advanced Materials, 35, 2211497.

  • Atomic-scale homogeneous Ru–Cu alloy nanoparticles for highly efficient electrocatalytic nitrogen reduction. (2022). Advanced Materials, 34, 22055270.

  • Generation of high-density nanoparticles in the carbothermal shock method. (2021). Science Advances, 7, eabk2984.

 

Yuhua Yang | Materials Chemistry | Best Researcher Award

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Dr. Yuhua Yang | Materials Chemistry | Best Researcher Award

Jiangxi Science and Technology Normal University | China

Dr. Yuhua Yang is an accomplished materials scientist specializing in nanomaterials synthesis and advanced electrochemical energy-storage systems, with a strong focus on lithium-ion and lithium-sulfur battery technologies. He holds a bachelor’s degree from Nanchang University, a master’s degree from Beijing University of Posts and Telecommunications, and a Ph.D. from Hunan University. He has significant industrial and academic experience, having served in roles at Haier Group, China Netcom Corporation, and Yichun University before joining the School of Materials and Energy at Jiangxi Science and Technology Normal University. His research portfolio centers on bio-derived nanostructures and engineered electrode materials designed to overcome critical battery challenges, including volume expansion, low coulombic efficiency, and poor cycle stability. Representative studies include innovative Sn-based and Ni-based electrodes derived from bacterial carbon and natural biotemplates, such as Bacillus subtilis-based carbon @Sn anodes and yolk-shell Ni₃P-carbon@graphene frameworks, demonstrating enhanced electrochemical stability and durability. His recent publications also explore advanced core-shell architectures and flexible bacterial-carbon/graphene systems , reflecting his continuing drive toward high-capacity, stable, and flexible battery platforms. Notably, his contribution to bacteria-derived carbon materials for Li-S batteries published in Nano Letters  has been cited 110 times, underscoring international recognition of his work. Across 15 indexed publications, Dr. Yang has accumulated 515 citations from 487 documents and holds an h-index of 7 in Scopus, indicating strong and growing impact in the fields of materials chemistry and energy storage. His innovative approach of integrating biological templates with advanced nanostructuring strategies provides sustainable pathways for next-generation battery materials, positioning him as a rising leader in energy and nanomaterials research.

Profile : Scopus 

Featured Publications

Li, F., Han, P.-T., … Yang, Y.-H. (2025). The core-shell structure of bacteria-based C@Sn/Carbon nanotubes exhibits super-stable cycling performance for lithium-ion battery anodes. Journal of Power Sources, 645.

Li, F., Han, P.-T., … Yang, Y.-H. (2025). Flexible Co₃(PO₄)₂@ bacterial carbon/reduced graphene oxides for Li-ion batteries anode. Materials Letters, 389.

Zhang, Z.-W., Li, F., … Yang, Y.-H. (2024). Ultra-high first coulombic efficiency and stable cycle performance of bacterial-based C/Sn/SnS nanomaterial for lithium-ion battery anodes. Chemical Physics Letters, 840.

Yang, Y.-H., Xi, Z.-C., … Zhou, J. (2023). Gram-positive bacteria Bacillus subtilis-based carbon @ Sn anode for high-performance Li-ion batteries. Journal of Materials Science: Materials in Electronics, 34(8).

Yang, Y.-H., Zhang, Z.-W., … Zhou, J. (2022). The photoluminescence materials of green light Gd₂O₃:Eu and its influencing factors. Journal of the Physical Society of Japan, 91(11).

T. T. Khaleelul Rahman | Materials Chemistry | Best Researcher Award

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Mr. T. T. Khaleelul Rahman | Materials Chemistry | Best Researcher Award

University of Calicut | India

T. T. Khaleelul Rahman is an emerging researcher in the fields of Material Science, Computational Physics, Nanoscience, and Energy Storage Technology, currently pursuing an Integrated M.Sc. in Physics at the University of Calicut, Kerala. His research bridges physics, nanotechnology, and sustainable materials, with a focus on developing advanced polymer nanocomposites for multifunctional applications including optoelectronics, antibacterial systems, and energy-related device engineering. Rahman has contributed to two peer-reviewed international publications, including articles in International Journal of Biological Macromolecules and Journal of Thermoplastic Composite Materials, where he co-developed bio-derived polymer composites reinforced with nanocurcumin and LiAgO-based nanostructures to enhance optical, mechanical, electrical, and antimicrobial properties. His research demonstrates a strong commitment to sustainable nanomaterials and green synthesis for next-generation technologies. His current Scopus metrics reflect 11 citations, 1 h-index, and contributions across 2 indexed documents, emphasizing his early-stage yet impactful scientific engagement. During his academic tenure, Rahman completed a competitive research internship at the Centre for Polymeric Science and Technology, University of Calicut, under the mentorship of Prof. M. T. Ramesan. He has also supported multiple nanocomposite-based research projects involving polymer blends, metal-oxide nanoparticles, and biogenic antimicrobial nanomaterials. His technical competencies span UV-Vis, FTIR, XRD, impedance spectroscopy, MATLAB, Origin, Mathematica, Python, and scientific visualization, strengthening his ability to perform multidisciplinary experimental and computational studies. Beyond research, Rahman is an experienced physics educator, active volunteer, and recipient of notable achievements including the Prof. Joseph Mundassery Scholarship and First Rank in CUCET. With strong academic excellence, proven research capability, and a vision toward sustainable advanced materials, Rahman exemplifies the qualities of a promising young scientist poised to contribute significantly to the scientific community.

Profiles : Scopus | ORCID | Google Scholar 

Featured Publications

Shabah, N. N., Rahman, T. T. K., Gopika, R., & Ramesan, M. T. (2025, July 7). Multifunctional polyvinyl alcohol/maranta arundinacea starch/LiAgO nanocomposites: A sustainable approach for antibacterial and optoelectronic applications. Journal of Thermoplastic Composite Materials.

Ramesan, M. T., Gopika, R., Rahman, T. T. K., Jamsheena, K. T., & Bahuleyan, B. K. (2025, April). Impact of nanocurcumin on mechanical, optical and electrical properties of chitosan/polyvinyl alcohol blend nanocomposites for sustainable applications. International Journal of Biological Macromolecules, 309, 142976.

Jinxiao Li | Inorganic Chemistry | Best Researcher Award

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Dr. Jinxiao Li | Inorganic Chemistry | Best Researcher Award

Dalian University | China

Dr. Jinxiao Li, currently affiliated with the College of Environmental and Chemical Engineering, Dalian University, is an accomplished researcher specializing in biomass-derived energy materials and sustainable energy conversion technologies. He earned his Ph.D. in Power Engineering and Engineering Thermophysics from Shandong University, where his doctoral research focused on the preparation of hierarchical porous carbon from plant-based materials and its application in supercapacitors. Over the past decade, Dr. Li has developed a robust research profile that bridges materials chemistry, renewable energy, and catalysis. Dr. Li’s research centers on biomass conversion, porous carbon fabrication, catalyst design, and hydrogen production. His innovative work on nitrogen-doped hierarchical porous carbons and activation techniques for improved electrochemical performance has significantly contributed to the development of high-efficiency supercapacitors and electrocatalytic systems. By integrating green synthesis methods and advanced characterization techniques such as BET, SEM-EDS, TEM, XRD, XPS, ICP, and FTIR, Dr. Li has advanced understanding of the structural-performance relationships in energy materials. With 21 publications, an impressive 1,291 citations, and an h-index of 14 (Scopus), Dr. Li’s scholarly output reflects both quality and influence in the field of energy materials and environmental chemistry. His work not only addresses fundamental scientific challenges but also offers practical implications for clean energy generation and carbon neutrality initiatives. In recognition of his research excellence, Dr. Li has been honored with the Dalian City Young Talents Award and the Outstanding College Graduates of Shandong Province Award. As an active expert member of the Dalian Energy Conservation Association, he continues to promote sustainable development through research and academic service. Dr. Li’s ongoing projects focus on next-generation biomass-based catalysts and hydrogen energy systems, positioning him as a leading figure in the pursuit of sustainable, high-performance energy materials.

Profiles : Scopus | ORCID

Featured Publications

  • Lian, M., Han, X., Li, J., Song, R., Yang, C., Zhang, J., Zhong, H., & Pan, L. (2025). Hierarchical porous carbon supports: Construction, mechanism, and catalytic performance as efficient microreactors for methanol steam reforming. Inorganic Chemistry Communications, 182(Part 2), 115561.

  • Zhao, Y.-e., Li, J., Xu, A., Liu, Y., Lian, M., Zhang, J., Zhong, H., Yang, C., Song, R., & Pan, L. (2025). Hierarchical porous carbon-supported bimetallic catalyst for enhanced low-temperature steam methane reforming. Catalysis Science & Technology.

  • Lv, S., Lian, S., Li, J., Wang, Y., Wei, J., Zhong, H., & Pan, L. (2025). Mechanochemical construction of stable Cu/MCM-41 with efficient hydrogen production via methanol steam reforming. International Journal of Hydrogen Energy, 164, 150818.

  • Li, J., Han, K., & Li, S. (2018). Porous carbons from Sargassum muticum prepared by H3PO4 and KOH activation for supercapacitors. Journal of Materials Science: Materials in Electronics.

Jianguang Xiao | Materials Chemistry | Best Researcher Award

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Prof. Jianguang Xiao | Materials Chemistry | Best Researcher Award

North University of China | China

Dr. Jianguang Xiao is an Associate Professor of Ordnance Science and Technology at North University of China, Ph.D., and supervisor for master’s degree candidates. Recognized as a Young Outstanding Talent of Shanxi Province’s “Sanjin Elite” Program, Dr. Xiao has made significant contributions to the study of reactive materials, explosion and shock dynamics, and target vulnerability assessment, particularly for UAVs, vehicles, and ammunition systems. His research integrates mechanics, thermotics, and chemistry, providing advanced modeling and simulation methods for reactive material behavior under high-velocity impact, energy release, and deflagration conditions. Dr. Xiao has led and participated in over twenty vertical and horizontal research projects, including funding from the National Natural Science Foundation of China, National Defense Foundation Projects, and Shanxi Provincial Natural Science Foundation. Notable projects include studies on the preparation and energy release characteristics of Tetrafluoroethylene-Hexafluoropropylene-Vinylidene Fluoride-based reactive materials and the development of integrated shock/deflagration material models. He has authored 28 high-level academic documents, including SCI and EI journal papers, one academic monograph, and holds three invention patents. His work has garnered 391 citations from 279 documents, achieving an h-index of 10, reflecting the significant impact of his research on the field of reactive materials and defense engineering. Dr. Xiao’s publications cover topics such as molecular dynamics simulation of chemical reactions, impact-induced deflagration behavior, and enhanced damage effects of reactive materials on concrete targets. Beyond research, Dr. Xiao actively contributes to the academic community. He serves on the youth editorial boards of journals including Journal of China Ordnance, Aeronautical Weaponry, and Journal of North University of China, and is a peer reviewer for prominent journals like Defence Technology and International Journal of Impact Engineering. He has been consecutively recognized as an Excellent Reviewer by multiple journals, emphasizing his commitment to maintaining high scholarly standards. Dr. Xiao’s interdisciplinary expertise, innovative contributions to reactive materials research, and active academic engagement make him a leading figure in his field, demonstrating both scientific excellence and practical impact.

Profiles : Scopus | ORCID | Research Gate

Featured Publications

  • Xiao, J., Zhang, J., Ma, J., et al. (2024). Mechanics–thermotics–chemistry coupling response model and numerical simulation of reactive materials under impact load. Advances in Engineering Software, 192, 103647.

  • An, D., Xiao, J.*, Ma, J., et al. (2024). Molecular dynamics simulation of chemical reactions in polytetrafluoroethylene-based reactive materials. Journal of North University of China (Natural Science Edition), 45(02), 222–228.

  • Nie, Z., Xiao, J., Wang, Y., & Xie, Z. (2022). Mechanical properties and ignition reaction characteristics of THV-based reactive materials. Journal of China Ordnance, 43(12), 3030.

  • Xiao, J., Nie, Z., Wang, Z., Du, Y., & Tang, E. (2020). Energy release behavior of Al/PTFE reactive materials powder in a closed chamber. Journal of Applied Physics, 127(16), 165106.

  • Xiao, J., Wang, Z., Nie, Z., Tang, E., & Zhang, X. (2020). Evaluation of Hugoniot parameters for unreacted Al/PTFE reactive materials by modified SHPB test. AIP Advances, 10(4), 045211.

 

Mihaela Georieva | Chemical Engineering | Best Researcher Award

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Assoc. Prof. Dr. Mihaela Georieva | Chemical Engineering | Best Researcher Award

Technical University of Sofia | Bulgaria

Dr. Mihaela Georgieva is an accomplished Associate Professor and Head of the Department of Chemistry at the Technical University of Sofia (TU-Sofia), Bulgaria. With over 18 years of research experience in the fields of electroless and electrochemical metallization, corrosion protection, and nanocomposite materials, she has established herself as a leading scientist in applied electrochemistry. Dr. Georgieva began her academic journey with a Bachelor’s and Master’s degree in Chemical Engineering from the University of Chemical Technology and Metallurgy, Sofia, specializing in Electrochemistry and Corrosion Protection. She earned her PhD in Physical Chemistry from the Bulgarian Academy of Sciences with a dissertation on the electroless deposition of copper composite coatings on polymer substrates. Her scientific output includes 31 peer-reviewed publications, co-authorship of 2 patents, and participation in 13 research projects, three of which she has led as a principal investigator. Her work has received 122 citations across 77 documents, and she holds an h-index of 7 (Scopus), reflecting the impact and visibility of her research in the scientific community. Dr. Georgieva is actively involved in national and European research collaborations and has presented her findings at numerous international conferences. She has also contributed as a reviewer for more than 10 academic journals. Her dedication to both teaching and research continues to inspire innovation in materials science and electrochemistry.

Profiles : Scopus | Orcid 

Featured Publications

  • Petrova, S., Lazarova, D., Georgieva, M., Petrova, M., Dobrev, D., & Ditchev, D. (2025). Metallization of 3D-printed PET and PETG samples with different filling densities of the inner layers. Materials, 18(14), 3401.

  • Petrova, M., Lazarova, D., Dobrev, D., Georgieva, M., & Petrova, S. (2025). Development of an environmentally friendly pre-treatment for electroless metallisation of glasses. Transactions of the IMF, 103(1), 1–8.

  • Georgieva, M., Lazarova, D., Petrova, M., & Dobreva, E. (2023). Selection of a suitable environmentally friendly (non-toxic) etching solution in the electroless metallisation of ABS polymers. Transactions of the IMF, 101(6), 321–329.

  • Georgieva, M., Lazarova, D., Petrova, M., Tzaneva, B., & Dobreva, E. (2023). Modification of the surface of ABS polymer by swelling operation and its influence on some properties of electroless deposited metal coatings. Transactions of the IMF, 101(1), 18–26.

  • Georgieva, M. G. (2022). Study of a system for creating a statistical model of the electroless plating of Cu-Ni-P alloys. Transactions of the IMF, 100(6), 345–351.

 

Myrtil Kahn | Coordination Chemistry | Best Researcher Award

Published on by Analytical Chemistry

Dr. Myrtil Kahn | Coordination Chemistry | Best Researcher Award

CNRS | France

Profiles

Scopus
Orcid

Early Academic Pursuits

Dr. Myrtil L. Kahn began her academic journey with a PhD in molecular compounds, under the supervision of a renowned expert in the field of coordination chemistry. Her doctoral work laid a strong foundation in molecular chemistry, which she later expanded into interdisciplinary domains. Her postdoctoral research included advanced work on ferrite nanoparticles and intermetallic particles, which positioned her at the intersection of nanoscience, materials chemistry, and applied physics.

Professional Endeavors

Following her postdoctoral experience, Dr. Kahn joined CNRS and quickly rose through the ranks to become a Senior Scientist and Research Director. She currently leads the “Nano-chemistry, Organization, and Sensors” team at the Laboratory of Coordination Chemistry (LCC) and also co-directs a multidisciplinary research initiative in collaboration with another leading national laboratory. This joint effort culminated in the establishment of a CNRS-affiliated joint research laboratory, reflecting her leadership in managing strategic partnerships with key industrial and governmental stakeholders, including aerospace and space agencies.

Contributions and Research Focus

Dr. Kahn’s research centers on nanoscience and its application to broad societal challenges such as energy, environment, space, aeronautics, and health. She has significantly contributed to the design and synthesis of hybrid nano-objects and multifunctional coatings. Her work focuses on controlling the structural and functional properties of nanoparticles particularly semiconductor and magnetic oxides and integrating them into real-world devices. Utilizing a safe-by-design philosophy, she innovates at the interface of molecular chemistry, surface science, and nanotechnology. Her research also emphasizes understanding surface-ligand interactions through advanced techniques like NMR spectroscopy, which is crucial for ensuring colloidal stability and optimizing material behavior in biological and industrial environments.

Impact and Influence

Dr. Kahn has established herself as a leader in applied nanosciences, successfully bridging fundamental chemistry with device integration. Her research has attracted substantial funding through over thirty competitive contracts, nearly half of which involve industrial collaborations. These projects have led to multiple patents with international extensions, showcasing her commitment to innovation and knowledge transfer. Beyond scientific output, her leadership in organizing large-scale conferences and her role in interdisciplinary teams underscore her influence across both academic and industrial landscapes.

Academic Citations

Her research excellence is reflected in her strong citation metrics. With thousands of citations and an impressive h-index, her work enjoys sustained recognition in the global scientific community. She has authored more than a hundred publications in peer-reviewed international journals, contributed to several book chapters, and is actively involved in reviewing and editorial responsibilities within leading scientific events and journals.

Technical Skills

Dr. Kahn possesses deep technical expertise in organometallic synthesis, nanoparticle surface chemistry, colloidal stability, and functional coatings. She has extensive experience in spectroscopic analysis, particularly NMR, for the investigation of ligand dynamics and surface coordination. Her proficiency extends to hybrid material fabrication, integration of nanoparticles into sensors and devices, and the development of safe-by-design methodologies. This multidisciplinary toolkit enables her to work effectively at the interface of chemistry, physics, and biology.

Teaching Experience

While her primary role is research-intensive, Dr. Kahn actively contributes to mentoring young researchers and postdoctoral fellows. She fosters scientific development through collaborative research, co-authorship, and direct supervision. Her mentorship style is marked by encouraging innovation and interdisciplinary approaches, preparing early-career scientists for careers in both academia and industry.

Legacy and Future Contributions

Dr. Kahn’s legacy is one of impactful science, interdisciplinary collaboration, and societal relevance. Her commitment to applied nanoscience has led to the development of novel materials and processes with potential applications in biotechnology, aerospace, and environmental technology. As co-director of a cutting-edge joint research lab, she continues to expand her collaborative reach, ensuring that her contributions influence the next generation of researchers. Her ongoing projects in multifunctional nanocomposites and hybrid processes promise continued breakthroughs in high-performance materials.

Notable Publications

Competition between ordered morphologies of functionalized silver nanoparticles elucidated by a joint experimental and multiscale theoretical study

Authors: David Loffreda; Nathalie Tarrat; Corinne Lacaze‑Dufaure; Franck Rabilloud; Katia Fajerwerg; Myrtil L. Kahn; Vincent Collière; Christine Lepetit; Pierre Fau
Journal: Nano Today
Year: 2025

Understanding Ion‑Exchange Processes in the Synthesis of ZnSₓ@ZnO₁₋ₓ Heterostructures from Controlled Sulfidation of ZnO Nanocrystals

Authors: Ekaterina Bellan; Martin Jakoobi; Vincent Collière; Yannick Coppel; Julien Trébosc; Olivier Lafon; Pierre Lecante; Paul Fleurat‑Lessard; Céline Dupont; Jean‑Cyrille Hierso; Pierre Fau; Katia Fajerwerg; Lauriane Pautrot‑d’Alençon; Thierry Le Mercier; Myrtil L. Kahn
Journal: Chemistry of Materials
Year: 2024

Spontaneous Emulsification of Organometallic Complexes Applied to the Synthesis of Nanocapsules Active for H₂ Release from Ammonia‑Borane

Authors: Olivier Gazil; Ludivine Rault; Déborah Iglicki; Vincent Collière; Gizem Karacaoglan; Didier Poinsot; Moad Bouzid; Jean‑Cyrille Hierso; Myrtil L. Kahn; Nick Virgilio; Fabienne Gauffre
Journal: Langmuir (The ACS Journal of Surfaces and Colloids)
Year: 2024

Synthesis of TiO₂/SBA‑15 Nanocomposites by Hydrolysis of Organometallic Ti Precursors for Photocatalytic NO Abatement

Authors: Ons El Atti; Julie Hot; Katia Fajerwerg; Christian Lorber; Bénédicte Lebeau; Andrey Ryzhikov; Myrtil L. Kahn; Vincent Collière; Yannick Coppel; Nicolas Ratel‑Ramond; Philippe Ménini; Pierre Fau
Journal: Inorganics
Year: 2024

Conclusion

Dr. Myrtil L. Kahn stands as a prominent figure in nanoscience and coordination chemistry. Her pioneering research, strong industrial collaborations, and leadership in both national and international scientific communities demonstrate her eligibility for high-level scientific honors. Through her interdisciplinary vision and dedication to real-world impact, she continues to shape the future of materials science and remains an exemplary model for academic and industrial synergy.

 

Khandoker Samaher Salem | Materials Chemistry | Best Researcher Award

Published on by Analytical Chemistry

Dr. Khandoker Samaher Salem | Materials Chemistry | Best Researcher Award

University of Dhaka, Bangladesh

👨‍🎓Profiles

Early Academic Pursuits

Dr. Khandoker Samaher Salem’s academic foundation is rooted in Applied Chemistry and Chemical Engineering from the University of Dhaka, where she graduated with top honors. Driven by a passion for materials science and sustainability, she pursued advanced studies abroad, earning both a Master’s in Materials Science and Engineering and a Ph.D. in Forest Biomaterials from North Carolina State University. Her graduate and doctoral training provided her with a strong interdisciplinary background, blending the fundamentals of polymer science, nanomaterials, and bio-based materials engineering.

Professional Endeavors

Dr. Salem currently serves as an Associate Professor in the Department of Applied Chemistry and Chemical Engineering at the University of Dhaka. Her academic career has steadily progressed through roles of increasing responsibility, reflecting her commitment to teaching, curriculum development, and institutional service. Her teaching portfolio covers a wide range of specialized subjects, including Materials Science, Polymer Engineering, and Chemical Technology, with a focus on pulp and paper, cellulosic fibers, and wood chemistry. She is actively involved in multiple university-level committees such as course development, academic discipline, and Outcome-Based Education (OBE) implementation.

Contributions and Research Focus

Dr. Salem’s research is centered on the fabrication and characterization of bio-based and polymeric materials with sustainable applications. Her work involves the development of cellulose nanofiber (CNF) films for packaging, biopolymer nano-hybrids, and grafted polymers, utilizing techniques such as freeze drying, cryogenic processing, solution casting, and composite lamination. Her scientific contributions aim to advance the fields of renewable materials and green chemistry, aligning with global sustainability goals. She also explores performance evaluation of these materials using both classical and advanced analytical tools.

Technical Proficiencies

Her laboratory competencies span a diverse range of material fabrication and testing techniques. She is adept in using instrumentation such as Scanning and Transmission Electron Microscopy (SEM, TEM), Time-of-Flight Secondary Ion Mass Spectrometry (ToF-SIMS), Instron mechanical testing, thermal analysis systems (DSC, TGA, DMA), FT-IR, UV-Vis, XRD, and optical profilometry. She also employs niche equipment like the Emtec TSA Softness Measurement Instrument and conducts permeability assessments (WVTR, OTR). Her computational skills extend to ImageJ, Origin Lab, ChemDraw, Adobe Creative Suite, and specialized software for materials analysis.

Teaching Experience and Academic Service

As a dedicated educator, Dr. Salem engages actively in undergraduate and postgraduate instruction, with class sizes ranging from 40 to 65 students. She has designed and delivered core and elective courses in polymer science and chemical engineering. Beyond teaching, she serves in advisory and curriculum roles, contributing to policy-making in academic and administrative spheres. Her involvement in student advising and undergraduate admissions underscores her holistic approach to academic mentorship.

Research Recognition and Honors

Dr. Salem’s scholarly excellence has been recognized through multiple competitive awards. These include first prize in a materials-focused Make-a-thon at NC State University and a prestigious enhancement fellowship for graduate students. Her research has earned national accolades, such as the National Science and ICT Fellowship, and university-level scholarships for academic distinction. These honors reflect her consistent performance as a top-tier scholar and emerging leader in materials research.

Industrial Exposure and Practical Insights

Dr. Salem complements her academic knowledge with hands-on exposure to industrial practices through various study tours across Bangladesh and the United States. These experiences have deepened her understanding of industrial chemical processes, quality control systems, utility operations, and sustainable material production, thereby enhancing her teaching and research with practical relevance.

Organizational Involvement and Outreach

She has demonstrated leadership in organizing international scientific events, such as the International Conclave on Materials, Energy and Climate, in partnership with the International Association of Advanced Materials (IAAM). Her involvement in community outreach programs in the U.S. during her studies—through initiatives like the ‘Cultural Corps’ and international festivals—highlights her commitment to intercultural exchange and science communication.

Professional Affiliations

Dr. Salem maintains active memberships in leading professional organizations including the American Chemical Society (ACS), the Society of Plastic Engineers (SPE), and the Bangladesh Chemical Society (BCS). These affiliations provide her with a global platform for networking, collaboration, and continuous learning.

Legacy and Future Contributions

Looking ahead, Dr. Salem aims to further integrate sustainable materials into mainstream engineering applications through cutting-edge research and academic leadership. She envisions a future where biodegradable and bio-sourced materials replace conventional plastics, with her research group at the forefront of this transition. Her dedication to innovation, pedagogy, and sustainability positions her as a catalyst for scientific progress in materials engineering both locally and internationally.

📖Notable Publications

Advances in barrier coatings and film technologies for achieving sustainable packaging of food products – a review
Authors: P. Tyagi, K.S. Salem, M.A. Hubbe, L. Pal
Journal: Trends in Food Science & Technology, 115, 461–485
Citations: 340
Year: 2021

Hydrogel-based sensor networks: Compositions, properties, and applications — A review
Authors: X. Sun, S. Agate, K.S. Salem, L. Lucia, L. Pal
Journal: ACS Applied Bio Materials, 4(1), 140–162
Citations: 250
Year: 2020

Comparison and assessment of methods for cellulose crystallinity determination
Authors: K.S. Salem, N.K. Kasera, M.A. Rahman, H. Jameel, Y. Habibi, S.J. Eichhorn, …
Journal: Chemical Society Reviews, 52(18), 6417–6446
Citations: 243
Year: 2023

Polyethylene glycol functionalized carbon nanotubes/gelatin-chitosan nanocomposite: An approach for significant drug release
Authors: S. Sharmeen, A.F.M.M. Rahman, M.M. Lubna, K.S. Salem, R. Islam, M.A. Khan
Journal: Bioactive Materials, 3(3), 236–244
Citations: 109
Year: 2018

Cellulase in waste management applications
Authors: M.N. Khan, I.Z. Luna, M.M. Islam, S. Sharmeen, K.S. Salem, T.U. Rashid, …
Journal: New and Future Developments in Microbial Biotechnology and Bioengineering
Citations: 56
Year: 2016