Xiaolu Yuan | Material Science | Research Excellence Award

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Dr. Xiaolu Yuan | Material Science | Research Excellence Award

University of Science and Technology Beijing | China

Yuan Xiaolu is a materials scientist specializing in diamond-based wide-bandgap semiconductors and advanced carbon materials. His research focuses on diamond material synthesis, surface conductivity engineering, high-performance diamond electronic devices, and carbon-based composites such as graphene–diamond and carbon nanotube/diamond systems with enhanced electrical, thermal, and photothermal properties. He has strong expertise in thin-film deposition, surface modification, interface engineering, and device fabrication, supported by extensive international research collaboration with leading institutions in Japan and China. He has published numerous peer-reviewed papers in high-impact journals covering diamond MOSFETs, ohmic contacts, all-carbon heterostructures, and ultra-efficient heat transport interfaces. His work bridges fundamental materials science and practical device applications. In addition, he holds multiple authorized invention patents related to diamond device fabrication, surface engineering, and carbon composite preparation. He also serves as a principal investigator and technical lead for a nationally funded project focused on diamond materials for self-powered heterogeneous integrated chip technologies.

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Eleni Efthimiadou | Material Science | Best Researcher Award

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Prof. Dr. Eleni Efthimiadou | Material Science | Best Researcher Award

National and Kapodistrian University of Athens | Greece

Eleni K. Efthimiadou is a distinguished academic and researcher in the field of Inorganic and Bioinorganic Chemistry, with a strong interdisciplinary focus on nanotechnology, nanomedicine, and advanced biomedical applications. She serves as a faculty member in the Laboratory of Inorganic Chemistry at the Department of Chemistry of the National and Kapodistrian University of Athens, where her work bridges fundamental chemistry with translational biomedical research. Her scientific expertise centers on the design, synthesis, surface modification, and physicochemical characterization of inorganic, organic, and hybrid nanomaterials with targeted biological functionality. A core aspect of her research is the development of multifunctional nanostructures—such as magnetic nanoparticles, gold and silver nanostructures, quantum dots, liposomal systems, and hybrid nanocomposites—for diagnostic, therapeutic, and theranostic applications. These systems are extensively evaluated through in vitro and in vivo biological models, addressing critical challenges in cancer diagnosis and treatment, inflammation-related diseases, antimicrobial resistance, and energy-related applications. She has extensive experience in advanced spectroscopic, microscopic, thermal, and magnetic characterization techniques, as well as in biological evaluation methodologies including cytotoxicity, oxidative stress, DNA interaction, apoptosis, angiogenesis inhibition, hyperthermia, and antimicrobial testing. Her in vivo research expertise includes biodistribution, biocompatibility, and therapeutic efficacy studies in established animal models, with full accreditation for laboratory animal research.Eleni K. Efthimiadou has made a substantial contribution to graduate and postgraduate education, having supervised a large number of undergraduate theses, master’s dissertations, and doctoral dissertations, many of which focus on cutting-edge nanochemical and biomedical research topics. She has also actively participated in doctoral and postgraduate examination committees in Greece and abroad. Her scholarly output includes a high volume of peer-reviewed publications in internationally recognized journals, with strong citation metrics reflecting significant scientific impact. Through her combined roles as researcher, educator, and mentor, she continues to advance the fields of bioinorganic chemistry and nanomedicine while fostering the next generation of scientists.

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Yun Liu | Material Science | Research Excellence Award

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Ms. Yun Liu | Material Science | Research Excellence Award 

Ms. Yun Liu | Beihua University | China

Yun Liu is a materials researcher affiliated with Beihua University, specializing in wood protection, wood anatomy, and weather-resistant material modification. With a strong academic foundation supported by a Master’s degree in Materials and Chemical Engineering, Yun Liu has developed expertise in material characterization, performance testing, and advanced analytical techniques used to evaluate structural, chemical, and aesthetic changes in lignocellulosic materials. A key contribution of Yun Liu’s work is the innovative investigation into the dynamic weathering behavior of heat-treated wood. This research integrates continuous monitoring of visual and structural degradation with in-depth chemical analysis, offering a holistic framework for understanding the durability of modified wood materials. By correlating changes in color, gloss, and surface properties with transformations in lignin, extractives, and microstructural features, the study provides essential insights into how heat treatment influences early-stage weathering. Importantly, the findings reveal that heat treatment adjusts the degradation pathways of lignin, contributing to enhanced color stability rather than merely slowing chemical deterioration. This mechanistic understanding supports the development of targeted modification strategies for improving the long-term service life and aesthetic performance of outdoor wood products. Yun Liu has published as first author in the journal Polymers, where the study on dynamic weathering of heat-treated Chinese fir highlights the scientific and practical relevance of this research. This work establishes a foundation for future advancements in sustainable wood protection technologies and environmentally conscious material engineering. Committed to academic integrity and professional growth, Yun Liu maintains active research links through recognized scholarly platforms and contributes to the broader scientific community through collaboration and knowledge dissemination. With a focus on innovation, material durability, and eco-friendly wood modification, Yun Liu aims to advance high-impact research aligned with the standards of the Research Excellence Award category.

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Featured Publications

Liu, Y., Gao, C., Wang, Q., Hadili, B., Miao, Y., Cui, X., & Matsumura, J. (2025). Dynamic weathering behavior of heat-treated Chinese fir: Surface properties, chemical composition, and microstructure. Polymers, 17(23), 3143. https://doi.org/10.3390/polym17233143

Dr. Sacha Cavelier | Material Science | Best Researcher Award | 2625

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Dr. Sacha Cavelier | Material Science | Best Researcher Award

Dr. Sacha Cavelier | Queensland University of Technology | Austria

Dr. Sacha Cavelier is a mechanical engineer and postdoctoral researcher at the Queensland University of Technology (QUT), specializing in advanced biomaterials, bone tissue engineering, and biomechanical characterization. Graduating as a biomedical-focused engineer from the École des Mines de Saint-Étienne (France), he advanced his research career through a Master’s and PhD in Mechanical Engineering at McGill University (Canada). His doctoral work introduced innovative strategies for next-generation bone graft materials, including multilayered titanium–calcium sulfate composites with superior strength, biocompatibility, and biodegradability, and led to multiple high-impact publications and patents. With more than seven years dedicated to developing ceramic-titanium bone graft composites, Dr. Cavelier has become a recognized expert in toughened biomaterials and bone regeneration. He further expanded his expertise during his postdoctoral fellowship at Ohio University, where he developed mineralized collagen scaffolds, supervised graduate students, and contributed to grant writing. At the University of Adelaide, he served as a visiting researcher, investigating the mechanical properties of human dura mater and pericranium. Currently at QUT’s ARC Centre for Cell & Tissue Engineering Technologies, Dr. Cavelier leads research on cartilage characterization, antibacterial coatings, and intramedullary implant technologies, including in vivo efficacy studies. He supervises PhD students, contributes to collaborative research programs, and continues to publish in leading journals such as Advanced Materials, Nanomaterials, Bioactive Materials, and Journal of the Mechanical Behavior of Biomedical Materials. Dr. Cavelier’s technical skillset spans additive manufacturing, finite-element modeling, biochemistry, mechanical testing, microscopy, and high-precision fabrication.

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Featured Publications

Yu, L., Cavelier, S., Hannon, B., & Wei, M. (2023). Recent development in multizonal scaffolds for osteochondral regeneration. Bioactive Materials, 25, 122–159.

Cavelier, S., Dastjerdi, A. K., McKee, M. D., & Barthelat, F. (2018). Bone toughness at the molecular scale: A model for fracture toughness using crosslinked osteopontin on synthetic and biogenic mineral substrates. Bone, 110, 304–311.

Cavelier, S., Mirmohammadi, S. A., & Barthelat, F. (2021). Titanium mesh-reinforced calcium sulfate for structural bone grafts. Journal of the Mechanical Behavior of Biomedical Materials, 118, 104461.

Cavelier, S., Quarrington, R. D., & Jones, C. F. (2022). Mechanical properties of porcine spinal dura mater and pericranium. Journal of the Mechanical Behavior of Biomedical Materials, 126, 105056.

Cavelier, S., Quarrington, R. D., & Jones, C. F. (2022). Tensile properties of human spinal dura mater and pericranium. Journal of Materials Science: Materials in Medicine, 34(1), Article 4.

Cavelier, S., Tanzer, M., & Barthelat, F. (2020). Maximizing the strength of calcium sulfate for structural bone grafts. Journal of Biomedical Materials Research Part A, 108(4), 963–971.

Mahesh Kumar Sah | Material Science | Best Researcher Award

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Dr. Mahesh Kumar Sah | Material Science | Best Researcher Award 

Dr. Mahesh Kumar Sah | Meerut Institute of Engineering and Technology | India

Dr. Mahesh Kumar Sah is a dedicated mechanical engineering professional with robust expertise in nano-finishing, surface engineering, composite materials, coating technology, image analysis, and design of experiments. With a Ph.D. from SRM Institute of Science and Technology, he brings a strong blend of academic, research, and industrial-oriented experience. His technical proficiency spans AutoCAD, SolidWorks, MATLAB, Origin, Minitab, and MS Office, enabling him to execute high-precision research and engineering tasks effectively. Dr. Sah has over six years of academic experience as an Assistant Professor at Siddartha Institute of Science and Technology, AP, where he handled a wide range of subjects including Engineering Mechanics, CAD/CAM, Robotics, Thermal Engineering, Manufacturing Technology, and Metrology. He also supervised laboratories, coordinated academic programs, and managed responsibilities related to seminars, projects, NBA/NAAC documentation, and student administration. Currently, he serves as a Project Associate-II at NIT Jalandhar, contributing to advanced mechanical engineering research. His research contributions include multiple SCI-indexed publications in reputable journals such as Materials and Manufacturing Processes, Canadian Metallurgical Quarterly, and Journal of Materials Engineering and Performance. His work primarily focuses on CNC abrasive finishing, reflective polishing, nano-finishing processes, and optical characterization of materials. He has also authored book chapters and reviewed research manuscripts for leading journals. Dr. Sah is the co-inventor of a filed patent titled “A System for Mirror-Like Reflective Surface Finishing on Metallic Cylindrical Workpiece” and has presented his research at several national and international conferences. He has completed NPTEL and FDP courses in surface engineering, machine learning, sustainability, nanotechnology, and entrepreneurship. Recognized with the Dr. APJ Abdul Kalam Research Award, Dr. Sah is a motivated researcher and educator committed to advancing mechanical engineering, fostering innovation, and contributing meaningfully to academia and industry.

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Featured Publications

Sah, M. K., Vijaya, A., & Singh, H. (2025). Nanofinishing of aluminum sheet using CNC fixed abrasive lapping. Journal of Materials Engineering and Performance. https://doi.org/10.1007/s11665-025-10886-3

Sah, M. K., Vijaya, A., & Singh, H. (2025). A novel CNC abrasive finishing process of aluminium pipe for industrial applications. Canadian Metallurgical Quarterly. https://doi.org/10.1080/00084433.2025.2582355

Sah, M. K., Vijaya, A., & Singh, H. (2025). Experimental study of the surface finishing of CNC magnetic abrasive finishing based on ANN. Canadian Metallurgical Quarterly. https://doi.org/10.1080/00084433.2024.2415726

Sah, M. K., & Vijaya, A. (2024). Optimizing highly reflective CNC abrasive polishing on aluminum sheets. Materials and Manufacturing Processes. https://doi.org/10.1080/10426914.2024.2304867

Sah, M. K., & Vijaya, A. (2023). Experimental studies on reflective finishing of aluminum sheet by CNC abrasive lapping. Materials and Manufacturing Processes. https://doi.org/10.1080/10426914.2023.2244034

Noboru Konda | Material Science | Best Researcher Award

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Prof. Dr. Noboru Konda | Material Science | Best Researcher Award

Prof. Dr. Noboru Konda | Ryukoku University | Japan

Prof. Noboru Konda is a distinguished materials science expert whose career spans academia, advanced engineering, and applied industrial research. Trained at Kyoto University and later awarded a doctorate from Osaka University, he established a strong foundation in metallurgical engineering early in his career. His professional journey began in the steel industry, where he contributed to the structural assessment and performance evaluation of thick steel plates. This experience deepened his understanding of material behavior under demanding conditions and guided his ongoing commitment to developing stronger and more reliable materials. Prof. Konda has made significant contributions to the study of fatigue crack growth, particularly in base materials and welded joints. His work explores how materials behave in both normal and corrosive environments, and he has successfully identified structural characteristics that enhance durability and resistance to failure. His research approach combines experimental investigations with advanced evaluation techniques, offering valuable insights for industries that rely on the long-term stability of metals and other structural components. At Ryukoku University, Prof. Konda continues to expand his research by investigating the strength, soundness, and degradation mechanisms of a broad range of materials, including metals, resin composites, wood, and rubber. His interdisciplinary focus addresses real-world challenges encountered in manufacturing, infrastructure, and product development. Beyond research, he actively mentors students, engages in collaborative projects, and contributes to the academic community through publications, expert reviews, and knowledge-sharing activities. His academic and industrial background allows him to bridge scientific innovation with practical application. With a career dedicated to understanding and improving material performance, Prof. Konda remains committed to advancing safe, efficient, and reliable engineering solutions. His work continues to support scientific progress, industrial development, and the broader field of materials engineering.

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Featured Publications

Konda, N., & Kayamori, Y. (2025). Fatigue properties of welded structural steels initiated from long-term corroded surfaces. Solid State Phenomena, Trans Tech Publications

Konda, N., Mori, M., Shindoh, Y., & Kitamura, T. (2025). Fatigue strength evaluation of linear friction welded joints for S55C steel plates. Welding International. Taylor & Francis.

Darvaish Khan | Material Science | Research Excellence Award

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Dr. Darvaish Khan | Material Science | Research Excellence Award

Dr. Darvaish Khan | Sapienza University of Rome | Italy

Dr. Darvaish Khan is a distinguished postdoctoral researcher at the Department of Chemical Engineering, Materials, and Environment, Sapienza University of Rome, Italy, with an extensive academic and research background in materials science, solid-state physics, and energy materials. He earned his Ph.D. in Materials Science and Engineering from Shanghai Jiao Tong University, China, following a Master’s from Liverpool Hope University, UK, and an M.Sc. in Solid State Physics from the University of Peshawar, Pakistan. Dr. Khan’s research primarily focuses on the design, synthesis, and characterization of metal hydrides, composites, and alloys for advanced hydrogen storage and energy applications. His expertise spans hydrogen-matter interactions, phase transitions in nanostructured environments, and modeling of solid-state metal hydrides using COMSOL Multiphysics. He has developed innovative materials through solid-state mechanochemical, hydrothermal, and wet-impregnation/infiltration methods, utilizing advanced characterization tools such as XRD, SEM, TEM, BET, DSC, TGA, FTIR, XPS, Raman spectroscopy, and Sieverts-type PCT for analyzing structural, thermal, and gas sorption properties. His work significantly contributes to improving the thermodynamics and kinetics of hydrogen sorption in metal hydrides and nanocomposites, addressing global challenges in sustainable hydrogen energy systems. Dr. Khan’s impactful research has been published in top-tier international journals, including Interdisciplinary Materials, Journal of Alloys and Compounds, ACS Applied Materials & Interfaces, Chemical Engineering Journal, and the International Journal of Hydrogen Energy. He has also served as a guest speaker at international conferences, received multiple research excellence awards, and is a reviewer for international scientific journals. As an HEC-approved Ph.D. supervisor and member of the American Chemical Society and International Society of Hydrogen Energy, Dr. Khan continues to advance interdisciplinary innovations in hydrogen storage, nanostructured materials, and sustainable energy technologies, contributing meaningfully to the global transition toward a hydrogen-based clean energy future.

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Featured Publications 

Zhu, W., Panda, S., Lu, C., Ma, Z., Khan, D., Dong, J., Sun, F., Xu, H., Zhang, Q., & Zou, J. (2020). Using a self-assembled two-dimensional MXene-based catalyst (2D-Ni@Ti₃C₂) to enhance hydrogen storage properties of MgH₂. ACS Applied Materials & Interfaces, 12(45), 50333–50343.

Ma, Z., Panda, S., Zhang, Q., Sun, F., Khan, D., Ding, W., & Zou, J. (2021). Improving hydrogen sorption performances of MgH₂ through nanoconfinement in a mesoporous CoS nano-boxes scaffold. Chemical Engineering Journal, 406, 126790.

Ma, Z., Zou, J., Khan, D., Zhu, W., Hu, C., Zeng, X., & Ding, W. (2019). Preparation and hydrogen storage properties of MgH₂-trimesic acid-TM MOF (TM = Co, Fe) composites. Journal of Materials Science & Technology, 35(10), 2132–2143.

Khan, D., Zou, J., Zeng, X., & Ding, W. (2018). Hydrogen storage properties of nanocrystalline Mg₂Ni prepared from compressed 2MgH₂–Ni powder. International Journal of Hydrogen Energy, 43(49), 22391–22400.

Ma, Z., Zhang, Q., Panda, S., Zhu, W., Sun, F., Khan, D., Dong, J., Ding, W., & Zou, J. (2020). In situ catalyzed and nanoconfined magnesium hydride nanocrystals in a Ni-MOF scaffold for hydrogen storage. Sustainable Energy & Fuels, 4(9), 4694–4703.

Hadiel Zamzam | Material Science | Best Researcher Award

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Dr. Hadiel Zamzam | Material Science | Best Researcher Award

Dr. Hadiel Zamzam | Suez University | Egypt

Dr. Hadiel Zamzam is a highly accomplished prosthodontist with a German educational foundation and American postdoctoral research experience. She currently serves as a Lecturer in Fixed Prosthodontics at Suez University and Misr International University (MIU), and as a Researcher at Egypt’s National Research Center (NRC). A meticulous clinician and innovative academic, Dr. Zamzam’s expertise spans fixed prosthodontics, esthetic rehabilitation, CAD/CAM restorative materials, and dental biomechanics. Their studies have been cited by 14 scientific documents, reflecting a growing impact within the dental research community. With an h-index of 1, the researcher’s work demonstrates an emerging academic influence supported by collaborative projects and experimental investigations on occlusal veneer durability, resin cement bonding, and surface treatment optimization. The publications showcase a strong integration of biomechanical analysis and material science, contributing to advancements in evidence-based restorative dentistry and digital dental technology.

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Featured Publications

Zamzam, H., Moussa, A., Zohdy, M., Morsi, T., Olivares, A., & Fok, A. (2025). Accelerated bruxism-simulating fatigue test of occlusal veneers. Journal of the Mechanical Behavior of Biomedical Materials, 157, 107243. https://doi.org/10.1016/j.jmbbm.2025.107243

Zamzam, H., Olivares, A., & Fok, A. (2021). Load capacity of occlusal veneers of different restorative CAD/CAM materials under lateral static loading. Journal of the Mechanical Behavior of Biomedical Materials, 115, 104290. https://doi.org/10.1016/j.jmbbm.2020.104290

 

siguo xiao | Material Science | Best Researcher Award

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Prof. siguo xiao | Material Science | Best Researcher Award

Prof. siguo xiao | Xiangtan University | China

Dr. Siguo Xiao is a distinguished Professor and Doctoral Supervisor specializing in optoelectronic technology and semiconductor physics. He teaches core courses such as Optoelectronic Technology and Semiconductor Physics, fostering innovation and practical expertise among graduate and doctoral students. His research focuses on solid-state luminescence, luminescent materials, and advanced optoelectronic applications, with interests spanning nanomaterials, optical glass and ceramics, and semiconductor optoelectronic technologies. Over his prolific career, Prof. Xiao has led or participated in more than ten major research projects, including the National Program, the National Natural Science Foundation of China (NSFC), and key initiatives supported by the Hunan Provincial Department of Science and Technology and the Department of Education. His project leadership includes notable NSFC-funded studies on semiconductor oxide/rare earth fluoride micro-nano composites and broadband quantum cutting luminescent materials Prof. Xiao has made significant scholarly contributions, authoring over 80 SCI/EI-indexed papers in high-impact journals such as Physical Review Letters, Optics Letters, Journal of Applied Physics, and RSC Advances. His research has achieved an impressive academic footprint, with 1,578 citations from 1,412 documents, 110 total publications, and an h-index of 23 — underscoring both the depth and influence of his scientific output. He is also an accomplished inventor with over ten national invention patents, including A Blue Up-Conversion Luminescent Material and Its Preparation Method and A Silicate Yellow Long-Lasting Phosphor and Its Preparation Method. Four of his patented technologies have been successfully transferred for industrial application, highlighting his commitment to translational research and technology commercialization. In recognition of his outstanding scientific achievements, Prof. Xiao received the Third Prize of the Hunan Provincial Science and Technology Progress Award. His mentorship has guided graduate students to notable accolades, including one Provincial Excellent Graduate Thesis and two Xiangtan University President’s Awards.

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Featured Publications

Li⁺ and B³⁺ Co-Doping Induced Near-Infrared Emission Enhancement of Ga₁.₆Sc₀.₄O₃:Cr³⁺. (2025). ECS Journal of Solid State Science and Technology.

Long-Wavelength Broadband Near-Infrared ZrTe₃O₈:Cr³⁺, Ti⁴⁺ Phosphor of High Luminescence Quantum Yield and Excellent Thermal Stability. (2025). ACS Applied Optical Materials.

Luminescence Improvement via Site Environment Adjustment and Site Occupancy Regulation of Eu²⁺ in Ca₈MgSi₄O₁₆Cl₂. (2025). Optical Materials.

Pure Near-Infrared Up-Conversion Emission of Tm³⁺ Sensitized by Ni²⁺ in MgGa₂O₄. (2024). Journal of Physical Chemistry C.

Broadband Near-Infrared Emission in Cr³⁺, Yb³⁺, Li⁺ Tri-Doped In₂TeO₆. (2024). Materials Research Bulletin.

Muhammad Sarfraz | Material Science | Best Researcher Award

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Assoc. Prof. Dr. Muhammad Sarfraz | Material Science | Best Researcher Award

Assoc. Prof. Dr. Muhammad Sarfraz | University of Engeineering and Technology | Pakistan

Dr. Muhammad Sarfraz, PhD, is an accomplished Associate Professor in the Department of Polymer and Process Engineering at the University of Engineering and Technology (UET), Lahore. He brings extensive expertise in membrane technology, polymer processing, and sustainable separation systems, with a strong focus on solutions addressing global challenges such as carbon capture, water purification, and energy-efficient processes. With academic training spanning B.Sc., M.Sc., and Ph.D. in Chemical and Polymer Engineering—including doctoral research at King Fahd University of Petroleum and Minerals (KSA)—Dr. Sarfraz has built a prolific research portfolio. His scholarly impact is reflected in 155 citations across 126 documents, 22 publications, and an h-index of 8. His contributions include high-impact publications, competitive national research grants, and the supervision of multiple postgraduate theses, alongside significant efforts in laboratory establishment and curriculum development at UET. As In-charge of the Membrane Research Lab at UET, he continues to drive innovation in advanced materials and separation technologies. Beyond research, Dr. Sarfraz plays an active role in the global scientific community as a reviewer, editorial board member, and academic council contributor, making him a recognized leader in his field.

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Featured Publications

Shahzadi, K., Sarfraz, M., Alomar, M., Al Huwayz, M., Riaz, A., Mujtaba, M. A., Bashir, M. N., & Petrů, J. (2025, November). Zn-Co nanoferrites incorporated polysulfone nanofiltration membranes for wastewater treatment. Polymer Testing, 126, 108993.

Nawaz, S., Sarfraz, M., Alomar, M., Al Huwayz, M., & AlMohamadi, H. (2025, August). Antifouling polyethersulfone-based interfacial polymerization membranes for water treatment applications. Journal of Polymer Research, 32, 4528.

Riaz, A., Wu, C., Li, X., Sarfraz, M., Sun, L., Liu, L., Song, Y., & Ma, X. (2025, June). Huge improved gas separation performance of carbon molecular sieve membranes by incorporating polyimide COF into a linear polyimide precursor. Journal of Membrane Science, 714, 124103.

Sabir, A., Alomar, M., Sarfraz, M., & Yasmeen, F. (2025, June 15). Modulating membrane performance by optimizing coagulation temperature and dipping time. Journal of Applied Polymer Science, 142, e56998.

Khan, H. A. A., Sarfraz, M., Gouadria, S., Al-Harbi, F. F., & Shahzadi, K. (2025, May 15). Enhancing carbon capture efficacy of titania-doped polyethersulfone membranes. Arabian Journal for Science and Engineering, 50, 10263.

Alomar, M., Nawaz, S., Sarfraz, M., & Sabir, A. (2025, March). Genipin nanoparticles-doped reduced graphene oxide membranes: A promising solution for arsenic ion removal from wastewater. Arabian Journal for Science and Engineering, 50, 9634.

Sarfraz, M., Alomar, M., Ma, X., & Riaz, A. (2024). Ameliorating carbon capture efficiency of polysulfone membranes via collegial incorporation of zeolite imidazole frameworks and carbon nanotubes. Journal of Applied Polymer Science, 141, e55707.

Tahir, Z., Alomar, M., Sarfraz, M., Waheed, A., & Ayub, H. M. U. (2024). Carbon capturing composite membranes comprising Cu-MOF and PIM-1. Journal of Applied Polymer Science, 141, e55709.

Sagar, S., Riaz, A., Hasanain, B., Bahadar, A., & Sarfraz, M. (2024). Deportment tuning of polymeric gas separation membranes: ZIF-L/PES nanocomposite. Arabian Journal for Science and Engineering, 49, 8522.

Sarfraz, M., Ayyaz, M., Rauf, A., Yaqoob, A., Ali, M. A., Siddique, S. A., Qureshi, A. M., Sarfraz, M. H., Aljowaie, R. M., & Almutairi, S. M. (2024). New pyrimidinone bearing aminomethylenes and Schiff bases as potent antioxidant, antibacterial, SARS-CoV-2, and COVID-19 main protease Mpro inhibitors: Design, synthesis, bioactivities, and computational studies. ACS Omega, 9(1), 9393–

Khalid, J., Tariq, Z., Sarfraz, M., Mahmoud, K. H., & Abid, N. (2024). Pilot scale trialing of multi-leaf spiral-wound polymer membrane modules for efficient carbon capture. Arabian Journal for Science and Engineering, 49, 8809.