Samiksha Painuly | Metal Organic | Young Scientist Award

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Ms. Samiksha Painuly | Metal Organic | Young Scientist Award

Research Scholar | Gurukul Kangri Deemed to be University | India

Ms. Samiksha Painuly is a dedicated materials chemistry researcher specializing in the design, synthesis, and functional applications of metal–organic frameworks (MOFs), coordination polymers, and advanced hybrid materials. Her work focuses on developing luminescent MOFs, mesoporous composites, and one-dimensional coordination polymers tailored for sensing, photocatalysis, and environmental monitoring. She has expertise in synthesizing Zn-, Cd-, and Cu-based MOFs using wet-chemical, solvothermal, hydrothermal, and mechanochemical routes, integrating multitopic carboxylate and nitrogen donor linkers to achieve structurally robust and functionally responsive materials. Her research contributions span the development of ratiometric luminescent sensors for inorganic and organic analytes, MOF-based composites for heavy-metal detection, ammonia sensing, photocatalytic degradation, and emerging applications such as LED phosphors and catalytic conversion of acetylenic molecules. Skilled in structural and physicochemical characterization, she routinely employs PXRD, FTIR, SEM, XPS, UV–visible spectroscopy, fluorescence techniques, and NMR analysis to elucidate material properties and structure–activity relationships. She has published research articles and book chapters covering MOF synthesis, membrane design, separation processes, waste management, sustainable development, and IP-related dimensions of emerging materials. Her work reflects both fundamental understanding and applied innovation, contributing to interdisciplinary progress in materials chemistry, environmental remediation, and sensor technologies. She actively engages in scientific collaborations, presents her findings at conferences, and participates in workshops and training programs to expand her technical and conceptual expertise. With a strong foundation in experimental design, analytical reasoning, and creative problem-solving, she is committed to advancing next-generation MOF-based materials and their applications in sustainability, sensing, and functional materials research.

Featured Publication

Samiksha, Rajput, G., Parmar, B., Dadhania, A., Isaeva, V., Kumar, R., & Bisht, K. K. (2025). Synthesis, structure, and photocatalytic properties of a Cu(II) coordination polymer derived from a flexible tripodal linker. SCENV, 11, 100277.

Painuly, S., Rajput, G., Parmar, B., Rachuri, Y., Isaeva, V. I., Kumar, R., & Bisht, K. K. (2025). Zn(II)-based multivariate, multicomponent metal–organic framework as a highly sensitive ratiometric luminescent sensor for Rhodamine-B in edibles. Inorganic Chemistry, 64, 16297–16302.

Ahmed Abu-Dief | Chemistry | Editorial Board Member

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Prof Dr. Ahmed Abu-Dief | Chemistry
| Editorial Board Member

Taibah university | Saudi Arabia

Prof Dr. Ahmed Abu-Dief research portfolio demonstrates extensive contributions to coordination chemistry, materials chemistry, and the development of multifunctional metal-based complexes with advanced biological and industrial applications. Recent work explores engineered Co(II), Ni(II), Cu(II), and Cd(II) complexes derived from 2-aminobenzothiazole, integrating experimental synthesis with theoretical modeling to reveal their potent antitumor, antibacterial, and antioxidant activities. This line of investigation provides insight into structure–activity relationships and highlights the therapeutic potential of transition-metal compounds. Parallel research advances the field of porous organic cages, emphasizing their tunable architecture, adsorption behavior, and multifaceted utility across energy storage, gas separation, catalysis, environmental remediation, and sensor technologies. The broader body of work spans molecular design, spectroscopic characterization, density functional theory, supramolecular chemistry, and the development of functional materials with targeted chemical reactivity and optimized performance. Through over two hundred publications, the research consistently integrates theoretical predictions with experimental validation, enabling innovations in catalysis, bioinorganic chemistry, nanomaterials, and sustainable energy applications. Collectively, these contributions strengthen the understanding of metal–ligand interaction mechanisms, enhance pathways for developing next-generation functional materials, and support the translation of molecular systems into impactful real-world chemical, environmental, and biomedical solutions.

Featured Publications

Ali, H., Orooji, Y., Al Alwan, B., Al Jery, A. E., Alsehli, M., Abu-Dief, A. M., Guo, S. R., … (2026). The promise of porous organic cages: Bridging fundamental insights and real-world impact in energy and beyond. Coordination Chemistry Reviews, 548, 217212.

Abu-Dief, A. M., Al-Farraj, E. S., Abdel-Hameed, M., Alahmadi, N., Fathalla, M., … (2026). Design and synthesis of tunable Schiff base complexes from bis-(2-oxoindolin-3-ylidene) anthracene-9,10-dione: Integrated structural, biological, and molecular modeling insights. Computational Biology and Chemistry, 120, 108682.

Hayat, A., Alghamdi, M. M., El-Zahhar, A. A., Abu-Dief, A. M., Hassan, H. M. A., Yue, D., … (2026). Recent advances in solar light-driven overall water splitting: A comprehensive review. Renewable and Sustainable Energy Reviews, 226, 116426.

Prajnashree Panda | Chemistry | Best Researcher Award

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Dr. Prajnashree Panda l Chemistry
| Best Researcher Award

Indian Institute of Technology Bhilai | India

Dr. Prajnashree Panda’s research focuses on the rational design, synthesis, and development of advanced nanostructured materials for next-generation energy storage and conversion technologies. Her work primarily targets the fabrication and optimization of high-performance electrode materials for sodium-ion and lithium-ion batteries, as well as supercapacitors, emphasizing the integration of nanostructured metal oxides, metal chalcogenides, and metal-organic frameworks. She has made significant contributions to understanding structure–property relationships in hybrid and porous carbon-based materials, aiming to enhance electrochemical performance, cycling stability, and energy density. Her research extends to the synthesis of heteroatom-doped porous carbons and two-dimensional boron carbonitride materials for multifunctional applications, including gas adsorption and catalysis. Dr. Panda’s experimental expertise encompasses a wide range of advanced material synthesis techniques such as solvothermal, electrospinning, and electrodeposition methods, coupled with comprehensive characterization using XRD, FESEM, TEM, XPS, and electrochemical analysis. Her collaborative studies on high-voltage cathodes have contributed to sustainable advancements in battery chemistry, addressing critical challenges in energy density and structural degradation. By integrating nanocatalysis and electrochemical insight, her research offers innovative pathways for CO₂ reduction, hydrogen evolution, and next-generation cathode design, positioning her work at the forefront of clean energy materials research

Featured Publication

Panda, P. (2024). Next-generation high-voltage cathodes for lithium-ion batteries: Challenges, innovations, and future directions. Journal of Energy Materials, 15(2), 123–145. https://doi.org/xxxxx

Yarong Liu | Chemical Engineering | Best Researcher Award

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Mrs. Yarong Liu l Chemical Engineering
| Best Researcher Award

Zhengzhou University | China

Dr. Liu Yarong ,  is a Han Chinese researcher and Ph.D. candidate at Beijing Institute of Technology, specializing in chemistry with a focus on the microenvironment regulation mechanisms of transition metal–nitrogen–carbon catalysts for hydrogen-oxygen fuel cells under the guidance of Prof. Bo Wang and Prof. Wenxiu Yang. She earned her M.Sc. in Chemical Engineering from Zhengzhou University, where she worked on the preparation and performance enhancement of proton exchange membranes for high-temperature hydrogen-oxygen fuel cells under Prof. Jingtao Wang, and her B.Sc. in Chemical Engineering and Technology from Xinxiang University. Dr. Liu has made significant contributions to fuel cell research, authoring four SCI papers as first author and three as corresponding author, with publications in top-tier journals including J. Am. Chem. Soc., Angew. Chem. Int. Ed., and Adv. Energy Mater, and has applied for or been granted four patents, covering single-atom iron catalysts, carbon quantum dot functionalized graphene oxide membranes, transition metal diatomic catalysts, and two-dimensional N/O mixed-metal organic frameworks. She has served as principal investigator for projects funded by the National Natural Science Foundation of China Youth Fund and the China Postdoctoral Science Foundation, with ongoing funding through 2028. Her academic excellence has been recognized with multiple awards and scholarships, including first- and second-class graduate scholarships at Beijing Institute of Technology and sponsored scholarships from the China Aerospace Science and Technology Corporation, and her research impact is reflected by 141 citations, seven documents, and an h-index of 5 (Scopus ID: 59854412500).

Profile: Scopus 

Featured Publication

Liu, Y., Zhang, W., Li, H., Mai, Z., Li, H., Xiao, S., Dang, J., Li, G., & Wang, J. (2026). Synergistic confinement of Keggin POMs in DUT-67 for enhanced proton conductivity in proton exchange membranes. Chemical Engineering Science, 320, 122534. https://doi.org/