Sk. Riyajuddin | Nanotechnology and Material Physics | Young Scientist Award

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Dr. Sk. Riyajuddin | Nanotechnology and Material Physics | Young Scientist Award

 Indian Institute of Technology (ISM) Dhanbad, India

Dr. Sk. Riyajuddin is a materials scientist specializing in nanotechnology, renewable energy, and advanced electronic materials, with a strong academic foundation spanning doctoral research in nano-carbon and non-carbon material interfaces, postgraduate training in condensed matter physics, and undergraduate studies in physics. His research expertise covers water splitting, green hydrogen generation, solar-driven energy conversion, graphene and CNT synthesis, hydrogen fuel cells, and supercapacitor devices. He possesses extensive hands-on experience with advanced characterization, fabrication, and electrochemical techniques, including electron microscopy, spectroscopy, thin-film deposition, lithography, and energy device testing. His scholarly excellence has been recognized through prestigious thesis honors, national-level competitive qualifications, and multiple merit-based scholarships. He has also received major competitive research funding and international academic recognition for his contributions to sustainable energy materials. In addition, his professional profile includes editorial responsibilities and consistent acknowledgment for academic merit and research excellence.

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Dr. Fatma Ouled Saad | Experimental Physics | Best Researcher Award

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Dr. Fatma Ouled Saad | Experimental Physics | Best Researcher Award

Dr. Fatma Ouled Saad | ENIM | Tunisia

Ouled Saad Fatma is a researcher in energetic engineering whose work focuses on thermal processes, renewable energy systems, and advanced methods for improving energy efficiency. She has contributed to the development and optimization of solar desalination technologies, particularly through innovative mechanisms designed to enhance solar still productivity and overall thermal performance. Her studies also explore the application of phase change materials to improve heat storage and transfer, supporting more effective energy capture and utilization in sustainable systems. Beyond renewable technologies, she has conducted significant research in electrical resistance tomography, offering new approaches for analyzing material properties and characterizing porosity in complex media. Her academic contributions extend to teaching and supervising projects in areas such as thermodynamics, fluid mechanics, refrigeration systems, sensors, and materials science, where she plays an active role in guiding students in applied engineering practices. Through her combined efforts in research, teaching, and project supervision, she consistently promotes innovative thinking and practical solutions in energy engineering. Her work reflects a strong commitment to advancing environmentally responsible technologies and improving the performance of thermal and energy systems. She is recognized for her ability to integrate experimental methods with analytical modeling to address engineering challenges. Her diverse contributions support progress in sustainable energy, applied thermal sciences, and diagnostic techniques for engineering materials.

Profile: Scopus 

Featured Publications

Ouled Saad, F., Madiouli, J., Mihoubi, D., Shigidi, I., & Sghaier, J. (2026). Estimating talc and cellulose porosity under mechanical dewatering using electrical resistance tomography technique. Flow Measurement and Instrumentation, 107, 103124.

Ouled Saad, F., Madiouli, J., Chemkhi, S., Mankai, S., & Shigidi, I. (2024). Increasing the productivity and the thermal efficiency of conventional solar stills using a new rotating discs mechanism. International Journal of Environmental Science and Technology. (Advance online publication)

Ouled Saad, F., Mankai, S., Madiouli, J., Chemkhi, S., Shigidi, I., & Khan, M. I. (2024). Effect of phase change materials melting temperature on improving single slope solar still productivity. Journal of Energy Storage. (Advance online publication)

Ouled Saad, F., Aymen, S., Madiouli, J., Jalila, S., & Olivier, F. (2016). Quadrupole method: A new approach for solving the direct problem of electrical resistance tomography. Journal of King Saud University – Science.

 

Dr. Meena S | Chemistry | Editorial Board Member

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Dr. Meena S | Chemistry | Editorial Board Member

Dr. Meena S | Dayananda Sagar College of Engineering | India

Dr. Meena S is a prominent chemist specializing in the synthesis and characterization of multifunctional ferrite-based nanomaterials with applications in photocatalysis, antibacterial activity, and electrochemical sensing. Her research emphasizes green and sustainable methods, including biofuel- and plant-mediated synthesis of nanocomposites, spinel ferrites, and metal-doped materials. She has contributed to developing advanced heterojunction nanomaterials for energy harvesting, environmental remediation, and healthcare applications. Dr. Meena’s work integrates structural, optical, and electrochemical studies to optimize material performance for photocatalytic and sensor-based applications. She has published extensively in high-impact journals such as Inorganic Chemistry Communications, ACS Omega, RSC Advances, and Desalination and Water Treatment, highlighting her expertise in nanomaterials and electrochemical systems. Her research includes exploring S-scheme photocatalysis, carbon-based electrode composites, and ferrite-mediated degradation of pollutants. She actively coordinates and organizes international conferences, webinars, and faculty development programs, promoting knowledge sharing and innovation. Dr. Meena has served as a Special Issue Editor in nanomaterials, contributing to advancing the field through editorial leadership. She has received multiple awards for research excellence, oral presentations, and invited talks, reflecting her scientific impact. Her work bridges chemistry, materials science, and sustainable technology development. She is recognized for mentoring students and fostering research collaborations across disciplines. Her studies in visible-light-driven photocatalysis and electrochemical sensors demonstrate practical applications in environmental and healthcare monitoring. Dr. Meena emphasizes the integration of fundamental research with applied technologies for societal benefit. Her innovative approaches in nanomaterial synthesis and characterization continue to influence emerging research trends. Her ongoing work aims to expand applications of ferrite and heterojunction nanocomposites in energy, sensing, and environmental fields. She is a leading figure in advancing nanotechnology research with a focus on functional materials and green chemistry.

Profiles: Orcid | Google Scholar

Featured Publications

Maiti, N., Chawla, R., Illakiya, T., Mohan, C. R., Meena, S., Sen, S., & George, A. S. (2025). Enhancing telemedicine workflow through secure image transmission. In Title of the Book (pp. xx–xx). IGI Global.

Swamy, S., Gurushantha, K., Meena, S., Shashidhar, S., Srinatha, N., Anantharaju, K. S., Aruna Kumar, D. B., Soumya, C., Deepa, D., & Desai, N. R. (2024). Clove oil mediated combustion method synthesised Dy stabilized lanthanum ferrite: Its application as photocatalyst and antibacterial agent. Desalination and Water Treatment, 320, 100785.

Swamy, S., Gurushantha, K., Keshavamurthy, K., Meena, S., Sreenivasa, S., Soumya, C., Shashidhar, S., Desai, N. R., & Aruna Kumar, D. B. (2024). Green fuel mediated Europium doped lanthanum ferrites: Synthesis, characterization, and their application as photocatalyst and antibacterial agents. Inorganic Chemistry Communications.

Roopashree, B. N., Gurushantha, K., Nagaraju Kottam, & Meena, S. (2024). Recent review on S-scheme photocatalysis. Water, Air, & Soil Pollution, 235, 570.

Pompapathi, K., Anantharaju, K. S., Karuppasamy, P., Meena, S., Uma, B., Siddegowda, S. B., Chowdhury, A. P., & Murthy, H. C. A. (2024). Visible-light-driven Mentha spicata L.-mediated Ag-doped Bi₂Zr₂O₇ nanocomposite for enhanced degradation of organic pollutants, electrochemical sensing, and antibacterial applications. ACS Environmental Au.

Prof. Dr. Saeed Jafarirad | Biophysics | Best Researcher Award 

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Prof. Dr. Saeed Jafarirad | Biophysics | Best Researcher Award 

Prof. Dr. Saeed Jafarirad | University of Tabriz | Iran

Dr. Saeed Jafarirad is a leading researcher in polymer chemistry, green nanotechnology, and biomaterials, recognized for his extensive contributions to biogenic nanostructures, eco-friendly nanoparticle synthesis, and advanced polymeric systems. His work integrates supramolecular chemistry, dendritic and polymeric architectures, cellulose-based and chitosan-based biopolymers, and innovative nano-drug delivery systems designed for therapeutic and theranostic applications. He has produced a large body of scientific output, including book chapters in major biomedical polymer encyclopedias, dozens of peer-reviewed journal articles, numerous conference presentations, national patents, and a wide range of scientific and industrial research projects. His recent publications highlight breakthroughs in slow-release nanofertilizers, phytochemical-mediated magnetic nanocomposites, and enhanced osteogenic and osteoconductive materials developed through green chemistry. His research also explores modulation of plant secondary metabolites using green-synthesized nanomaterials, as well as environmentally friendly fabrication of metal oxide nanostructures for biological and agricultural use. Throughout his career, he has advanced the design of sustainable nanomaterials, self-assembly systems, and carbosiloxane-based dendritic hybrids with applications in drug delivery and controlled release. His contributions have strengthened interdisciplinary links between polymer science, biotechnology, and environmental nanotechnology. He has been frequently recognized for research excellence through awards at institutional and regional levels. Through his innovative approaches and consistent scientific productivity, Dr. Jafarirad continues to play a significant role in shaping the future of green nanotechnology, functional polymers, and bio-based nanomaterial engineering.

Profile: Google Scholar

Featured Publications

Jafarirad, S., Mehrabi, M., Divband, B., & Kosari-Nasab, M. (2016). Biofabrication of zinc oxide nanoparticles using fruit extract of Rosa canina and their toxic potential against bacteria: A mechanistic approach. Materials Science and Engineering: C, 59, 296–302.

Ebadollahi, R., Jafarirad, S., Kosari-Nasab, M., & Mahjouri, S. (2019). Effect of explant source, perlite nanoparticles and TiO₂/perlite nanocomposites on phytochemical composition of metabolites in callus cultures of Hypericum perforatum. Scientific Reports, 9(1), 12998.

Namazi, H., & Jafarirad, S. (2011). Application of hybrid organic/inorganic dendritic ABA type triblock copolymers as new nanocarriers in drug delivery systems. International Journal of Polymeric Materials, 60(9), 603–619.

Gharehpapagh, A. C., Farahpour, M. R., & Jafarirad, S. (2021). The biological synthesis of gold/perlite nanocomposite using Urtica dioica extract and its chitosan-capped derivative for healing wounds infected with methicillin-resistant bacteria. International Journal of Biological Macromolecules, 183, 447–456.

Daghian, S. G., Farahpour, M. R., & Jafarirad, S. (2021). Biological fabrication and electrostatic attractions of new layered silver/talc nanocomposite using Lawsonia inermis L. and its chitosan-capped inorganic/organic hybrid. Materials Science and Engineering: C, 128, 112294.

Assoc. Prof. Dr. Jonas Duarte | Carbon Allotropes | Outstanding Contribution Award

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Assoc. Prof. Dr. Jonas Duarte | Carbon Allotropes | Outstanding Contribution Award

Assoc. Prof. Dr. Jonas Duarte | Federal University of Western Pará | Brazil

Professor Jonas Marinho Duarte is a leading researcher in nanotechnology, with a primary focus on the detection of Majorana fermions and electronic transport phenomena in nanodevices based on the Kitaev chain. His work extensively employs Green’s function methods to model and analyze quantum transport in low-dimensional systems. He also utilizes ab initio calculations to simulate the electronic properties of graphene-like 2D materials, providing insights into charge transport behavior in molecular nanoelectronics. His research spans both one-dimensional and two-dimensional carbon allotropes, exploring their computationally predicted electronic transport properties. He has contributed to the development of nanodevices for potential applications in telecommunications and molecular electronics. Professor Duarte’s publications appear in reputable journals such as Computational Condensed Matter, PHYSICA E, and Optical and Quantum Electronics. His studies combine theoretical modeling with computational simulations to advance understanding of quantum transport mechanisms. He actively collaborates with institutions such as the Federal University of Pará, fostering interdisciplinary research. His contributions have potential implications for future quantum computing and nanoelectronic devices. By integrating concepts from physics, electrical engineering, and materials science, his work bridges fundamental theory and practical applications. Professor Duarte is also engaged in exploring 1D and 2D carbon-based nanomaterials for enhanced electronic functionality. His research provides valuable insights into the design and optimization of nanoscale electronic systems. Through his studies, he continues to push the boundaries of molecular and low-dimensional electronics. His work not only deepens theoretical understanding but also informs experimental approaches in nanodevice fabrication. He is recognized for his innovative applications of computational methods to complex quantum systems, establishing him as a prominent figure in the field of nanotechnology.

Profile: Orcid

Featured Publications

Cardoso, D. H., Miranda, I. R. S., Mota, E. A. V., Duarte, J. M., dos Santos da Silva, S. J., da Silva, C. A. B., & Del Nero, J. (2025). Numerical implementation of phagraphene as patch resonator for a microstrip antenna. Optical and Quantum Electronics.

Quaresma, L. C., Ferreira, D. F. S., Duarte, J. M., Moreira, M. M., da Silva, C. A. B., Jr., & Del Nero, J. (2025, December). Eigenchannel visualization and transition-voltage spectroscopy in two-dimensional C-57 allotrope. Computational Condensed Matter.

Quaresma, L. C., Duarte, J. M., Ferreira, D. F. S., da Silva, C. A. B., Jr., & Del Nero, J. (2025, October). Electronic transport modulation in C-57: A path toward carbon-based logic and switching devices. Physica E: Low-dimensional Systems and Nanostructures.

Duarte, J. M., Santos, J. C. S., Ferreira, D. F. S., Paula, M. V. S., Mota, E. A. V., Silva, C. A. B., & Del Nero, J. (2025, March). Systematic investigation of a metallic quadrilateral nanoribbon graphene allotrope for application in nanoelectronics. Computational Condensed Matter.

Duarte, J. M. (2024, November 1). Metodologias ativas e educação ambiental: uma revisão integrativa sobre abordagens inovadoras para o ensino de energia solar. Ensino e Tecnologia em Revista.

Assoc. Prof. Dr. Atsuomi Kimura | Experimental Physics | Best Researcher Award 

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Assoc. Prof. Dr. Atsuomi Kimura | Experimental Physics | Best Researcher Award 

Assoc. Prof. Dr. Atsuomi Kimura | The University of Osaka | Japan

Dr. Atsuomi Kimura is a highly respected researcher in the field of medical imaging and magnetic resonance technology at Osaka University, where his work focuses on the development and application of hyperpolarized ¹²⁹Xe MRI/MRS for advanced biomedical research. He has made significant contributions to improving imaging sensitivity and diagnostic accuracy, particularly in the study of lung function, disease detection, and therapeutic monitoring. His research emphasizes the innovative use of hyperpolarized noble gases to visualize physiological processes in ways that conventional imaging methods cannot achieve. By combining expertise in pharmacology, medical physics, and biomedical engineering, Dr. Kimura is advancing the integration of nanomedicine and magnetic resonance for precise, non-invasive diagnostic systems. His work on hyperpolarized xenon NMR technology has led to improved robustness, reproducibility, and sustainability, strengthening its application in both medical and materials science. He is deeply committed to translating experimental imaging techniques into practical clinical tools that enhance early disease detection and personalized treatment planning. Through his interdisciplinary approach, he bridges gaps between physics, chemistry, and life sciences, fostering innovations that drive next-generation imaging platforms. His research not only contributes to understanding complex biological systems but also supports the development of highly sensitive lung cancer detection methods. Dr. Kimura is actively involved in several professional societies in Japan, promoting collaboration and knowledge exchange in analytical chemistry and magnetic resonance research. His dedication to scientific advancement, combined with his innovative spirit, continues to influence the global field of medical imaging.

Profiles: Scopus | Orcid

Featured Publications

Kimura, A., Shimokawa, A., Stewart, N. J., Imai, H., & Fujiwara, H. (2025). Relationship between pulmonary gas exchange function and brain uptake dynamics investigated with hyperpolarized ¹²⁹Xe MR imaging and spectroscopy in a murine model of chronic obstructive pulmonary disease. Magnetic Resonance in Medical Sciences.

Fujiwara, H., Imai, H., & Kimura, A. (2025). Proposition of hyper‐chemical exchange saturation transfer subtraction spectroscopy to detect very weak and broad signals hidden under baseline and widen range of materials accessed by hyperpolarized ¹²⁹Xe NMR. ChemPhysChem.

Kimura, A., Shimokawa, A., Stewart, N. J., Hosoi, R., Imai, H., & Fujiwara, H. (2025). Ethyl pyruvate promotes wound healing in elastase-induced lung injury in mice as assessed by hyperpolarized ¹²⁹Xe magnetic resonance imaging. Preprint.

Fujiwara, H., Imai, H., & Kimura, A. (2024). Development of stopped-flow hyper-CEST NMR method on recirculating hyperpolarization system as applied to void space analysis in polymers. Analytical Sciences.

Kimura, A., Utsumi, S., Shimokawa, A., Nishimori, R., Hosoi, R., Stewart, N. J., Imai, H., & Fujiwara, H. (2022). Targeted imaging of lung cancer with hyperpolarized ¹²⁹Xe MRI using surface-modified iron oxide nanoparticles as molecular contrast agents. Cancers, 14(24), 6070.

Innovation in Atomic Research Award

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Introduction: Welcome to the forefront of groundbreaking discoveries! The 'Innovation in Atomic Research Award' celebrates pioneers pushing the boundaries of atomic research, recognizing exceptional contributions to scientific advancement.

Award Overview: Eligibility: Open to researchers worldwide, irrespective of age. Qualification: Individuals with a background in atomic research, regardless of academic affiliation. Publications: A minimum of three impactful publications in atomic research. Requirements: Demonstrate substantial progress in the field through verifiable achievements.

Evaluation Criteria: Submissions evaluated based on innovation, impact, and contribution to atomic research.

Submission Guidelines: Follow detailed guidelines for submission to ensure your work is considered.

Recognition: Winners receive global recognition, highlighting their pivotal role in atomic research.

Community Impact: Emphasize the broader impact of your research on the scientific community and society.