Rafael Bernardo Carmona-Paredes | Materials Science | Best Researcher Award

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Dr. Rafael Bernardo Carmona-Paredes | Materials Science | Best Researcher Award

National Autonomous University of Mexico | Mexico

Dr. Rafael Bernardo Carmona-Paredes is a highly respected academic and researcher specializing in hydraulic engineering, water resources management, and dynamic systems. With a career spanning over four decades, he has contributed extensively to both theoretical and applied aspects of water systems engineering. Currently serving at the Universidad Nacional Autónoma de México (UNAM), Dr. Carmona has dedicated his career to advancing hydraulic transients, pumping systems, aquifer recharge, and optimization of water distribution systems. His strong academic background, combined with innovative research and teaching, has enabled him to influence both national and international projects in water management and infrastructure. He has published widely in prestigious journals indexed in Scopus and JCR, authored book chapters, and developed patents related to hydraulic simulation and optimization. Dr. Carmona is also recognized for mentoring young researchers, guiding graduate students, and collaborating with institutions across Latin America and Europe. His professional excellence is further evident in his leadership roles within engineering associations and his frequent participation in international congresses. With a unique balance of academic rigor, applied engineering expertise, and societal impact, Dr. Carmona continues to be a leading figure in advancing sustainable solutions for global water challenges.

Professional Profile

Scopus Profile

Education

Dr. Rafael Bernardo Carmona-Paredes pursued his academic training entirely at the prestigious Universidad Nacional Autónoma de México (UNAM), where he cultivated a multidisciplinary foundation bridging physics, control engineering, and mechanical engineering. He completed his Bachelor’s degree in Physics, which provided him with a solid understanding of fundamental scientific principles, including fluid dynamics, mechanics, and applied mathematics. Motivated by the challenges of engineering applications, he advanced to earn his Master’s degree in Control Engineering, where he specialized in system modeling, dynamic controls, and mathematical optimization. This phase of study laid the groundwork for his future work in hydraulic systems and dynamic behavior of pipelines and water distribution networks. Building upon his expertise, Dr. Carmona earned his Ph.D. in Mechanical Engineering at UNAM, with a dissertation that focused on mathematical modeling for navigation and port water areas. His doctoral research represented an early integration of computational methods with hydraulic and mechanical engineering, pioneering approaches that remain highly relevant today. This combination of degrees reflects his progression from theoretical sciences to applied engineering, equipping him with the interdisciplinary knowledge essential for addressing complex problems in hydraulic engineering and water resources management.

Professional Experience

Dr. Rafael Bernardo Carmona-Paredes has held an illustrious professional career rooted in both academia and applied research. He has been a professor and researcher at the Faculty of Engineering, Universidad Nacional Autónoma de México (UNAM), where he has significantly contributed to teaching, supervising graduate students, and leading research initiatives. Over the years, he has spearheaded numerous national and international projects related to hydraulic engineering, water distribution systems, and aquifer management. His professional expertise extends beyond teaching into consultancy and applied engineering, where he has collaborated with governmental agencies, private organizations, and research institutions in solving water management challenges. Dr. Carmona has also been actively involved in presenting his work at major international forums such as the International Association for Hydro-Environment Engineering and Research (IAHR) and Latin American Hydraulic Congresses, establishing himself as a global voice in water engineering. He has contributed to the development of simulation models for transient flows, optimization techniques for pumping systems, and innovative strategies for aquifer recharge. His professional experience showcases a seamless blend of academic leadership, practical problem-solving, and active participation in the global engineering community, making him a sought-after expert in his field.

Research Interests

Dr. Rafael Bernardo Carmona-Paredes’ research interests focus on advancing the science and practice of hydraulic engineering, with a special emphasis on addressing water resource challenges. His primary area of interest lies in hydraulic transients, where he explores the dynamic behavior of water flow in pressurized systems and pipelines, including the effects of viscoelastic properties. He is deeply engaged in the study of pumping systems, their energy efficiency, and methods for optimizing their operation to achieve sustainable outcomes. Another significant focus of his research is aquifer recharge and groundwater management, where he integrates hydrological modeling with engineering approaches to enhance water security. Dr. Carmona also investigates reservoir operation policies, developing computational models that help optimize water storage and distribution under varying climatic and demand conditions. His work extends into mathematical modeling and control systems, leveraging his interdisciplinary background in physics and engineering to simulate complex water systems. By combining theoretical models with practical applications, his research provides innovative solutions for urban water distribution, infrastructure resilience, and sustainable resource management. His interests align with global efforts to ensure water sustainability, positioning his contributions as both regionally impactful and internationally relevant.

Research Skills

Dr. Rafael Bernardo Carmona-Paredes possesses a rich skill set that spans theoretical, computational, and applied aspects of hydraulic engineering and water resource systems. His expertise in mathematical modeling and simulation allows him to design complex models of hydraulic transients, aquifer recharge, and pumping systems with high accuracy. He is skilled in control systems engineering, applying advanced optimization methods to improve the performance and efficiency of water distribution networks. His proficiency extends to computational fluid dynamics (CFD), enabling him to analyze fluid behavior under transient and steady-state conditions. Additionally, Dr. Carmona demonstrates strong abilities in reservoir operation modeling, particularly in developing strategies for water conservation and sustainable supply. His technical strengths are complemented by his knowledge of hydrological data analysis, dynamic system modeling, and viscoelastic pipeline behavior. Beyond technical skills, he excels in research communication through scholarly publications, book chapters, and patents, as well as in collaborative skills through partnerships with international universities and engineering institutions. His ability to integrate theoretical rigor with practical applications reflects his comprehensive research capabilities, equipping him to address multidisciplinary challenges in water engineering and contribute to sustainable development goals.

Awards and Honors

Over the course of his career, Dr. Rafael Bernardo Carmona-Paredes has been recognized with numerous academic and professional honors for his contributions to hydraulic engineering and water resource management. His pioneering research has led to over 200 scientific publications in high-impact journals and conferences, many of which are indexed in Scopus and JCR, highlighting his influence in the global academic community. He has also authored book chapters and holds patents in hydraulic simulation systems, showcasing his ability to translate research into practical innovations. Dr. Carmona has been invited to present at international forums, including IAHR and Latin American Hydraulic Congresses, where his work has been acknowledged by peers worldwide. His role as a mentor and educator at UNAM has also earned him recognition within academic circles for shaping future generations of engineers and researchers. In addition to academic achievements, Dr. Carmona’s applied engineering solutions for aquifer management and hydraulic transients have earned him commendations from research and professional organizations. Collectively, these awards and honors reflect not only his scholarly excellence but also his significant impact on sustainable water engineering practices, both regionally and internationally.

Publication Top Notes

  1. Unsteady and Steady Flow Control on Pumping Systems — 1990

  2. Damp trend Grey Model forecasting method for airline industry — 2013

  3. Pressure management in water distribution systems using a self-tuning controller to distribute the available potable water with equality — 2018

  4. Protecting a Pumping Pipeline System from Low Pressure Transients by Using Air Pockets: A Case Study — 2019

  5. A Unified Hydrogeological Conceptual Model of the Mexico Basin Aquifer after a Century of Groundwater Exploitation — 2022

  6. Challenges and Experiences of Managed Aquifer Recharge in the Mexico City Metropolitan Area — 2022

  7. Use of evolutionary computation and guide curves to optimize the operating policies of a reservoir system established to supply drinking water — 2023

  8. Modeling Viscoelastic Behavior of HDPE Pipes Subjected to a Diametral Load Using the Standard Linear Solid Model — 2025

Conclusion

Dr. Rafael Bernardo Carmona-Paredes stands out as a visionary researcher and academic leader in the field of hydraulic engineering and water resource management. His academic journey from physics to mechanical engineering, paired with his practical expertise, has positioned him as a pioneer in developing innovative solutions for water-related challenges. His contributions extend from theoretical models of hydraulic transients to practical strategies for aquifer recharge and water distribution optimization, bridging the gap between science and application. Beyond his research, Dr. Carmona’s dedication to teaching and mentoring reflects his commitment to shaping future engineers, while his collaborations with global institutions highlight his influence beyond national borders. His vast publication record, patents, and recognition at international forums serve as a testament to his academic excellence and societal impact. Moving forward, his continued focus on sustainability, technological innovation, and global collaboration promises to further strengthen his contributions to water security and hydraulic engineering. For his pioneering achievements, leadership, and dedication, Dr. Rafael Bernardo Carmona-Paredes is rightfully considered a leading figure in his field and a deserving candidate for distinguished academic recognition.

Juan de Pablo | Materials Science | Best Researcher Award

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Prof. Juan de Pablo | Materials Science | Best Researcher Award

Professor and Vice President from New York University, United States

Dr. Juan José de Pablo is a globally recognized leader in molecular engineering, materials science, and chemical engineering, known for his groundbreaking research and extensive leadership in academic and national scientific organizations. Currently serving as the Executive Vice President for Global Science and Technology and Executive Dean at the Tandon School of Engineering, New York University, Dr. de Pablo has had an illustrious academic and professional journey. He is also a senior scientist at Argonne National Laboratory and has held pivotal roles at the University of Chicago and the University of Wisconsin. His work spans multiple research areas, including directed self-assembly of polymers, soft materials, molecular simulation, and biotechnology. Over the years, Dr. de Pablo has established himself as a prolific researcher with over 20 patents, numerous influential publications, and editorial positions in high-impact journals. He is an elected member of prestigious institutions including the U.S. National Academy of Sciences, the National Academy of Engineering, and the American Academy of Arts and Sciences. His leadership has influenced science policy, strategic research initiatives, and interdisciplinary collaborations across the globe. His contributions are not only scientific but visionary, paving the way for future technological advances in materials design, nanotechnology, and energy solutions.

Professional Profile

Education

Dr. de Pablo’s academic foundation is as impressive as his professional accomplishments. He began his education at the National University of Mexico (UNAM), where he earned a Bachelor of Science in Chemical Engineering in 1985. His passion for chemical engineering led him to pursue a doctoral degree at the University of California, Berkeley, where he received his Ph.D. in Chemical Engineering in 1990. After completing his doctorate, he furthered his research capabilities during a postdoctoral fellowship in Materials Science at the Institute for Polymers, ETH Zurich, Switzerland, from 1990 to 1992. These formative years provided him with a robust interdisciplinary background that blends engineering principles with advanced materials science. His exposure to leading institutions in North America and Europe gave him a global perspective early in his career, which continues to shape his international collaborations and leadership roles. The rigorous training he received laid the groundwork for his expertise in thermodynamics, polymer physics, and computational modeling, which would go on to influence countless innovations in both academic and industrial domains.

Professional Experience

Dr. de Pablo’s professional career spans over three decades and includes a distinguished trajectory of teaching, research, and leadership. He began his academic career as an Assistant Professor of Chemical Engineering at the University of Wisconsin in 1992, rising through the ranks to become a full professor and eventually Director of its Materials Research Science and Engineering Center. From 2000 to 2012, he also served as Deputy Director of the Nanoscale Science and Engineering Center. In 2012, he joined the University of Chicago as the Liew Family Professor at the Institute for Molecular Engineering, and later took on pivotal roles including Co-Director of the Center for Hierarchical Materials Design (CHiMaD) and Deputy Director for Education and Outreach. Since 2018, he has also been CEO of UChicago-Argonne LLC. Dr. de Pablo’s influence extends beyond academia into national and global science leadership, particularly through his vice presidency roles related to U.S. National Laboratories and global innovation. In 2024, he was appointed Executive Dean at NYU’s Tandon School of Engineering, a role through which he continues to shape engineering education and research strategy. His extensive professional background reflects a unique combination of scientific innovation and strategic governance.

Research Interests

Dr. de Pablo’s research interests are both broad and deep, focusing on the intersection of molecular engineering, materials science, and computational physics. A primary focus of his work is on the directed self-assembly of block copolymers, a field in which he has pioneered several methodologies now used in nanomanufacturing and lithography. He also investigates thermophysical properties of soft materials, advanced polymer systems, biological interfaces, and molecular thermodynamics. His interest in computational modeling has led to the development of new simulation tools and theoretical frameworks for studying molecular and nanoscale systems, facilitating predictions of material behavior with high accuracy. Additionally, Dr. de Pablo has contributed significantly to biotechnology research, particularly in areas related to cryopreservation, stem cell engineering, and synthetic biology. His interdisciplinary approach allows him to tackle complex problems that span chemistry, physics, and engineering. Through collaborative projects and centers such as CHiMaD, he works closely with experimentalists to translate computational models into real-world applications. His research agenda reflects an enduring commitment to solving fundamental scientific challenges while also addressing practical issues in health, energy, and technology.

Research Skills

Dr. de Pablo possesses an exceptional array of research skills that reflect his training and contributions across multiple scientific disciplines. He is a world leader in computational modeling and molecular simulation, applying these techniques to study the thermodynamic and kinetic behavior of polymers, colloids, and biological systems. His skillset includes advanced knowledge of coarse-grained and multiscale simulations, free energy calculations, and structure-property prediction methods. Beyond computational proficiency, he has deep expertise in thermodynamics, statistical mechanics, and polymer physics. His laboratory and theoretical work complement each other, allowing him to bridge gaps between experimental observations and theoretical predictions. He is also adept at integrating interdisciplinary methods, including those from materials science, chemical engineering, and applied physics. His ability to conceptualize and lead large-scale research initiatives, such as the Materials Genome Initiative, highlights his strengths in research strategy and innovation management. In mentoring and supervision, Dr. de Pablo has guided dozens of Ph.D. students and postdoctoral fellows, instilling in them a rigorous and holistic research methodology. His technical versatility and collaborative mindset are key reasons behind his influential role in shaping modern materials science.

Awards and Honors

Dr. de Pablo has been the recipient of numerous prestigious awards and honors that reflect the depth, breadth, and impact of his scientific career. Early in his career, he received multiple young investigator awards from leading institutions like NSF, IBM, Xerox, 3M, and DuPont, signaling his early promise. He went on to receive the Presidential Faculty Fellow Award from President Bill Clinton and was later elected as a Fellow of the American Physical Society and the American Academy of Arts and Sciences. His research has been recognized through lectureships and invited professorships at top global institutions such as ETH Zurich, Stanford, and the University of Michigan. He has delivered keynote talks and plenary lectures at more than 30 prestigious conferences and universities worldwide. In 2016, he was elected to the U.S. National Academy of Engineering and later to the National Academy of Sciences in 2022. Internationally, he holds honors like the Marie Curie Professorship and the Chevalier de l’Ordre du Mérite (France, 2024). His accolades also include the Polymer Physics Prize from the American Physical Society and numerous distinguished lectureships from Caltech, MIT, Princeton, and others. These honors underline his status as a leading global authority in materials and molecular engineering.

Conclusion

Dr. Juan José de Pablo exemplifies excellence in scientific research, innovation, and leadership. His prolific academic career, paired with his impactful administrative and advisory roles, highlights a rare combination of deep technical expertise and visionary leadership. His contributions to molecular engineering and materials science have not only expanded fundamental scientific understanding but have also enabled new technologies in fields ranging from nanolithography to cryopreservation. With over 20 patents, numerous high-impact publications, and a strong track record of mentorship, Dr. de Pablo has influenced both the academic community and industrial applications. His election to multiple national academies and his global recognition through prestigious awards are testaments to the quality and impact of his work. While already an established authority, he continues to contribute actively through roles in science policy, research strategy, and education at the highest levels. In summary, Dr. de Pablo’s lifelong dedication to advancing science and mentoring the next generation of researchers makes him a truly deserving candidate for the Best Researcher Award. His career serves as an inspiration and a benchmark for excellence in global scientific leadership.

Publications Top Notes

  1. Water-mediated ion transport in an anion exchange membrane
    Nature Communications, 2025
    Citations: 2
  2. Structural studies of the IFNλ4 receptor complex using cryoEM enabled by protein engineering
    Nature Communications, 2025
    Citations: 1
  3. Reflection and refraction of directrons at the interface
    Proceedings of the National Academy of Sciences of the United States of America, 2025
  4. Free-Energy Landscapes and Surface Dynamics in Methane Activation on Ni(511) via Machine Learning and Enhanced Sampling
    ACS Catalysis, 2025
  5. Synthetic Active Liquid Crystals Powered by Acoustic Waves
    Advanced Materials, 2025
  6. Current Advances in Genome Modeling Across Length Scales 2025
  7. Chromatin structures from integrated AI and polymer physics model
    PLOS Computational Biology, 2025
    Citations: 1
  8. A Twist on Controlling the Equilibrium of Dynamic Thia-Michael Reactions
    Journal of Organic Chemistry, 2025
  9. Bio-Based Surfactants via Borrowing Hydrogen Catalysis
    Chemistry – A European Journal, 2025
  10. Efficient sampling of free energy landscapes with functions in Sobolev spaces
    Journal of Chemical Physics, 2025
    Citations: 1

Hanaa Abd El-Hamid | Materials Science | Best Researcher Award

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Assoc. Prof. Dr. Hanaa Abd El-Hamid | Materials Science | Best Researcher Award

Associate Professor from National Research Centre, Egypt

Hanaa Kamel Abd El-Hamid Essway is an accomplished Egyptian researcher specializing in ceramics, refractory, and building materials with extensive expertise in bioactive and sustainable materials. she currently serves as an Assistant Professor at the National Research Centre. With over 20 years of progressive experience, Dr. Essway has built a strong research portfolio focusing on the development of innovative materials for biomedical, dental, and structural applications. Her research emphasizes the use of cost-effective and eco-friendly materials, aligning her work with both scientific advancement and environmental sustainability. She has published numerous articles in highly regarded international journals such as Ceramics International, Scientific Reports, and Heliyon, covering critical areas like bio-cements, corrosion-resistant coatings, and dental restorative materials. In addition to her research, she is actively involved in training and mentoring university students and has participated in several national and international conferences. Dr. Essway possesses a strong blend of practical laboratory expertise and theoretical knowledge, and she continuously seeks to contribute to the advancement of material science. Her career reflects her dedication to scientific excellence, continuous learning, and impactful research that addresses real-world challenges.

Professional Profile

Education

Dr. Hanaa Kamel Abd El-Hamid Essway has pursued a solid academic path that firmly established her expertise in chemistry and materials science. She earned her Ph.D. in Chemistry from Ain Shams University, Egypt, in 2013. Her doctoral research, titled “Utilization of Egyptian Oil Shales in Manufacture of High-Belite Cement and Activated Pozzolanic Ash,” focused on sustainable and cost-efficient materials for construction, demonstrating her early commitment to resource-efficient technologies. Before her doctoral studies, she completed her Master’s degree in Chemistry in 2006 from Menufiya University, where she conducted in-depth studies on the use of Egyptian oil shales in cement production. Her Master’s research laid the groundwork for her doctoral investigations and subsequent career focus on eco-friendly building materials. Dr. Essway began her academic journey by earning a Bachelor’s degree in Chemistry from Menufiya University in 1999 with high distinction, graduating with an overall rating of “Very Good.” Her continuous educational progression from undergraduate studies to advanced research degrees reflects her sustained academic dedication and expertise in her field. These educational achievements have provided her with a comprehensive understanding of both theoretical chemistry and its practical applications in material development.

Professional Experience

Dr. Hanaa Kamel Abd El-Hamid Essway has demonstrated consistent career growth through her long-standing association with the National Research Centre in Egypt. She currently holds the position of Assistant Professor in the Ceramics, Refractory, and Building Materials Department, a role she has occupied since February 2023. Her academic journey within the Centre began in 2001 as a Research Assistant, and she gradually progressed through the ranks as an Assistant Researcher, Researcher, and finally Assistant Professor. Between 2006 and 2013, she served as an Assistant Researcher, where she honed her skills in developing novel materials for biomedical and structural use. Following this, she worked as a full-time Researcher until 2023, during which she made significant research contributions, particularly in the area of bio-cement and corrosion-resistant coatings. Over her career, Dr. Essway has participated in several specialized training courses, student mentorship programs, and international scientific conferences. Her professional experience not only showcases her research capabilities but also highlights her ability to apply her scientific knowledge in real-world materials development. This long-term commitment to research and education has positioned her as a highly respected expert in her field.

Research Interest

Dr. Hanaa Kamel Abd El-Hamid Essway’s research interests are deeply rooted in the development of sustainable, cost-effective, and bioactive materials for use in various industrial and biomedical applications. She is particularly focused on ceramics, bio-cement, corrosion-resistant coatings, and dental restorative materials. One of her primary areas of investigation is the utilization of locally available, low-cost materials such as Egyptian oil shales and soda-lime-silica glass in cement and bioactive composites, aiming to reduce manufacturing costs while enhancing material performance. Her work on nano-structured coatings for corrosion protection and biocompatible composites has significant potential for medical implants and dental applications. Additionally, Dr. Essway is interested in the hydration behavior and remineralization potential of modified cements, exploring how novel composites can improve the strength and longevity of dental restorations. Her cross-disciplinary research approach integrates chemistry, materials science, and biomedical engineering, contributing to both environmental sustainability and human health. Dr. Essway’s research is geared toward solving real-world challenges by improving material properties such as biocompatibility, antibacterial resistance, and mechanical durability, making her work highly relevant for industries such as healthcare, construction, and biomaterials development.

Research Skills

Dr. Hanaa Kamel Abd El-Hamid Essway possesses a diverse and advanced set of research skills that reflect her hands-on expertise in experimental design, material synthesis, and analytical characterization. She is highly skilled in developing and modifying bioactive cements, corrosion-resistant coatings, and nano-structured materials, applying polymeric methods and microwave combustion techniques for precise material fabrication. Dr. Essway’s extensive experience includes characterizing materials using advanced techniques to study microstructures, hydration behaviors, and bioactivity. She has effectively contributed to the synthesis of tricalcium silicate bio-cements, nano-alumina coatings, and zinc oxide-based composites with antibacterial and biocompatible properties. Additionally, she is proficient in evaluating the mechanical properties and corrosion resistance of coating layers, which is essential for biomedical applications. Dr. Essway is adept at using statistical tools and research methodologies for data interpretation and scientific reporting. She also has strong computer skills, particularly in Microsoft Office applications, which she uses for scientific writing and data management. Her ability to collaborate with multidisciplinary teams, conduct literature reviews, and supervise laboratory experiments further strengthens her research portfolio. Her continuous participation in training workshops and scientific conferences has allowed her to stay updated with modern research methodologies and industry practices.

Awards and Honors

While specific award titles were not listed, Dr. Hanaa Kamel Abd El-Hamid Essway’s career achievements demonstrate significant recognition within the scientific community. Her long-standing role at the National Research Centre and her progression to Assistant Professor underscore the institutional trust and recognition of her capabilities and contributions. Throughout her career, she has been actively involved in major research projects, student mentorship, and national-level training initiatives, which reflect her respected standing as both a researcher and educator. Dr. Essway has participated in several high-profile international and national conferences, where she has presented her work alongside leading experts in material science and biomaterials. Her published articles in top-tier journals such as Ceramics International, Scientific Reports, and Heliyon are further testament to the scientific community’s acknowledgment of the value and relevance of her research. Her engagement in skill development programs and training workshops, including scientific writing and occupational safety, shows her commitment to continuous improvement. The cumulative impact of her scientific contributions, teaching, and professional development indicate that she is a well-regarded figure in her field, deserving of recognition through honors such as the Best Researcher Award.

Conclusion

In conclusion, Dr. Hanaa Kamel Abd El-Hamid Essway stands out as a dedicated and accomplished researcher whose work significantly advances the fields of ceramics, bio-cement, and sustainable building materials. Her research is characterized by innovation, interdisciplinary approaches, and practical solutions that address real-world challenges in biomedical and construction applications. With more than 20 years of progressive experience, she has contributed extensively to the scientific community through impactful publications, participation in conferences, and mentorship of university students. Dr. Essway’s focus on using cost-effective and locally sourced materials aligns her work with global sustainability goals while simultaneously pushing the frontiers of material performance and safety. Her research skills, including advanced synthesis techniques, material characterization, and data analysis, have consistently yielded valuable findings that are well-recognized by international journals. Although her work would benefit from greater international collaboration and leadership roles, her proven research productivity and technical expertise make her a strong candidate for prestigious research awards. Dr. Essway’s career exemplifies the qualities of a Best Researcher Award recipient: dedication, innovation, academic excellence, and a tangible contribution to society

Publications Top Notes

1. Alkali Activation of Blended Cements Containing Oil Shale Ash

  • Authors: M.M. Radwan, L.M. Farag, S.A. Abo-El-Enein, H.K. Abd El-Hamid

  • Journal: Construction and Building Materials 40, 367-377

  • Year: 2013

  • Citations: 29

2. Preparation and Characterization of Nano-Tetracalcium Phosphate Coating on Titanium Substrate

  • Authors: M.M.R. M. Fathi, H.K. Abd El-Hamid

  • Journal: International Journal of Electrochemical Science 11, 3164-3178

  • Year: 2016

  • Citations: 17

3. Influence of Saline Solution on Hydration Behavior of β-Dicalcium Silicate in Comparison with Biphasic Calcium Phosphate/Hydroxyapatite Bio-Ceramics

  • Authors: M.M. Radwan, H.K. Abd El-Hamid, A.F. Mohamed

  • Journal: Materials Science and Engineering: C 57, 355-362

  • Year: 2015

  • Citations: 17

4. Physico-Mechanical Characteristics of Tri-Calcium Silicate Pastes as Dentin Substitute and Interface Analysis in Class II Cavities: Effect of CaCl₂ and SBF Solutions

  • Authors: M.M. Radwan, S.M. Nagi, H.K. Abd El-Hamid

  • Journal: Heliyon 5 (6)

  • Year: 2019

  • Citations: 16

5. Influence of Nano-Silica Additions on Hydration Characteristics and Cytotoxicity of Calcium Aluminate as Biomaterial

  • Authors: H.K. Abd El-Hamid, M.M. Radwan

  • Journal: Heliyon 5 (7)

  • Year: 2019

  • Citations: 13

6. Synthesis, Properties and Hydration Characteristics of Novel Nano-Size Mineral Trioxide and Tetracalcium Phosphate for Dental Applications

  • Authors: M.M. Radwan, H.K. Abd El-Hamid, S.M. Nagi

  • Journal: Oriental Journal of Chemistry 32 (5), 2459

  • Year: 2016

  • Citations: 12

7. Characterization, Bioactivity Investigation and Cytotoxicity of Borosilicate Glass/Dicalcium Silicate Composites

  • Authors: R.L.E., H.K. Abd El-Hamid, S.M. Abo-Naf

  • Journal: Journal of Non-Crystalline Solids 512, 25-32

  • Year: 2019

  • Citations: 11

8. Evaluation of Bioactivity, Biocompatibility, and Antibacterial Properties of Tricalcium Silicate Bone Cement Modified with Wollastonite/Fluorapatite Glass and Glass-Ceramic

  • Authors: H.K. Abd El-Hamid, A.M. Fayad, R.L. Elwan

  • Journal: Ceramics International 50 (14), 25322-25332

  • Year: 2024

  • Citations: 10

9. Incorporation of Strontium Borosilicate Bioactive Glass in Calcium Aluminate Biocement: Physicomechanical, Bioactivity and Antimicrobial Properties

  • Authors: H.K. Abd El-Hamid, A.A. El-Kheshen, A.M. Abdou, R.L. Elwan

  • Journal: Journal of the Mechanical Behavior of Biomedical Materials 144, 105976

  • Year: 2023

  • Citations: 8

10. Synthesis, Characterization and Antimicrobial Activity of Nano-Crystalline Tricalcium Silicate Bio-Cement

  • Authors: H.K. Abd El-Hamid, H.H. Abo-Almaged, M.M. Radwan

  • Journal: Journal of Applied Pharmaceutical Science 7 (10), 001-008

  • Year: 2017

  • Citations: 8

 

 

Bin Lu | Materials Science | Best Innovator Award

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Assist. Prof. Dr. Bin Lu | Materials Science | Best Innovator Award

Associate Professor from Ningbo University, China

Dr. Bin Lu is an Associate Professor at the School of Materials Science and Chemical Engineering, Ningbo University, China. Since earning his Ph.D. in Materials Science and Engineering from the University of Tsukuba, Japan, in 2015, Dr. Lu has made significant contributions to the fields of optical functional ceramics, luminescent materials, and gas-sensing materials. He currently serves as a backbone researcher at Ningbo University and is affiliated with the Key Laboratory of Photoelectric Materials and Devices of Zhejiang Province. Dr. Lu’s research career is marked by a robust portfolio of over 50 peer-reviewed publications and 11 patents, which highlight his innovative approaches to material development and characterization. He has successfully led 10 funded research projects, focusing on advanced ceramics with applications in optics and electronics. His contributions have been recognized with the prestigious “Zhejiang Provincial Qianjiang Talent” title in 2017. Dr. Lu is highly regarded for his expertise in structural and photoluminescent analysis of ceramic materials and is a leading innovator in the development of transparent ceramics and magneto-optical devices. His academic excellence and research productivity make him a strong candidate for prestigious research and innovation awards, especially those honoring groundbreaking contributions in materials science and engineering.

Professional Profile

Education

Dr. Bin Lu holds a Ph.D. in Materials Science and Engineering from the University of Tsukuba, Japan, where he completed advanced training in ceramic materials and their optical properties. His doctoral work laid the foundation for his career-long interest in optical functional ceramics and luminescent materials. Prior to that, he obtained his Master of Science degree from Northeastern University in China, where he focused on fundamental principles of materials engineering, including crystallography, thermodynamics, and sintering processes. The strong academic foundation acquired through his undergraduate and postgraduate studies enabled him to pursue innovative research in materials science. His education across top-tier institutions in China and Japan provided a diverse and interdisciplinary approach to scientific inquiry, encouraging a blend of theoretical and practical perspectives in his research. During his academic training, Dr. Lu actively engaged in laboratory research, experimental material synthesis, and characterization techniques. This background empowered him with the analytical tools necessary for pioneering work in the design of ceramic materials for advanced functional applications. His academic credentials demonstrate a solid understanding of both the foundational and applied aspects of materials science, making him well-equipped to lead research initiatives in advanced ceramic development and optoelectronic material innovation.

Professional Experience

Dr. Bin Lu began his professional career in 2016 as a backbone researcher at the School of Materials Science and Chemical Engineering, Ningbo University, China. His position placed him at the core of several interdisciplinary research initiatives focused on the development of optical ceramics and luminescent materials. As a recognized expert in the field, Dr. Lu was entrusted with overseeing material design, characterization, and synthesis projects, contributing both to academic research and industrial applications. His affiliation with the Key Laboratory of Photoelectric Materials and Devices of Zhejiang Province further positioned him at the forefront of regional scientific advancement. As an Associate Professor, Dr. Lu has led numerous research projects supported by national and provincial funding bodies, with a strong focus on high-transparency ceramics, magneto-optical materials, and gas-sensing systems. Under his supervision, many of these projects have yielded patents and publications in high-impact journals, confirming his contributions to the scientific community. Dr. Lu also plays an active role in mentoring graduate students, coordinating laboratory experiments, and developing new research directions aligned with industry trends. His ongoing collaborations with leading researchers in China and abroad reflect his reputation as a dependable and forward-thinking materials scientist with a focus on practical innovation.

Research Interests

Dr. Bin Lu’s research is centered on the development and application of advanced ceramic materials with specialized optical and luminescent properties. His primary research interests include optical functional ceramics such as transparent ceramics, magneto-optical ceramics, and ceramic scintillators, which are integral to applications in laser technologies, radiation detection, and photonic devices. He is also deeply engaged in the design of luminescent materials and ceramic phosphors, focusing on mechanisms of upconversion, downconversion, and energy transfer for lighting and display technologies. In addition, Dr. Lu explores the synthesis and optimization of gas-sensing materials, particularly semiconductive ceramics, that offer high sensitivity and stability for environmental monitoring. His work integrates solid-state chemistry, crystallographic analysis, and materials processing techniques to achieve high-performance ceramic systems with tunable optical characteristics. Dr. Lu is especially interested in the role of additives and dopants in tailoring ceramic microstructures and enhancing material functionalities. His comprehensive approach—combining theoretical modeling, material fabrication, and property evaluation—allows for the innovation of multifunctional ceramic systems. These research pursuits not only contribute to academic knowledge but also meet practical demands in sectors such as energy, defense, healthcare, and smart sensing technologies.

Research Skills

Dr. Bin Lu is highly skilled in advanced materials synthesis and characterization techniques, particularly as they pertain to ceramic systems. He specializes in vacuum and pressure-assisted sintering, hot pressing, and solid-state reaction methods for producing high-purity, transparent, and luminescent ceramic materials. His expertise includes microstructural engineering of ceramics using rare-earth and transition metal dopants, aimed at optimizing optical and magneto-optical properties. Dr. Lu is proficient in utilizing a variety of analytical instruments such as X-ray diffraction (XRD), scanning and transmission electron microscopy (SEM/TEM), photoluminescence spectroscopy, UV-vis-NIR spectroscopy, and Hall effect measurements for comprehensive material analysis. Additionally, he employs Judd-Ofelt theory and other spectroscopic models to quantify the optical performance of luminescent ceramics. His ability to tailor the electrical, thermal, and photonic characteristics of ceramics demonstrates a deep understanding of structure-property relationships in complex oxides. Dr. Lu’s methodological rigor is evident in his systematic study of the effects of compositional variation, processing conditions, and structural defects on material behavior. Furthermore, his strong project management skills and collaborative mindset allow him to effectively lead multidisciplinary research teams and coordinate with academic and industrial partners to translate laboratory findings into real-world applications.

Awards and Honors

Dr. Bin Lu’s contributions to materials science have been recognized with several prestigious awards, most notably the “Zhejiang Provincial Qianjiang Talent” title, which he received in 2017. This honor is awarded to promising researchers in Zhejiang Province who demonstrate outstanding potential in academic research and innovation. The Qianjiang Talent award underscores Dr. Lu’s impact and leadership in developing advanced optical materials with practical applications. His work has also been consistently supported through competitive grants from national and regional funding agencies, reflecting the scientific and societal value of his research. In addition to formal awards, Dr. Lu has achieved recognition through publication in top-tier journals such as Acta Materialia, Journal of the American Ceramic Society, and ACS Applied Electronic Materials. His inventions have led to the filing and granting of 11 patents, further evidencing his capability to innovate beyond the academic sphere. Dr. Lu’s collaborative work with international research institutions and his role in advancing photoelectric materials at the provincial level also serve as informal acknowledgments of his professional excellence. These achievements collectively highlight his suitability for accolades that honor scientific innovation and applied research contributions.

Conclusion

Dr. Bin Lu stands out as a strong candidate for the Best Innovator Award in Research due to his exceptional accomplishments in the field of optical functional ceramics and luminescent materials. His track record of high-impact publications, patents, and successful research projects demonstrates not only his deep scientific expertise but also his ability to translate research into practical innovations. He excels in integrating advanced synthesis techniques with comprehensive analytical approaches, leading to breakthroughs in transparent and magneto-optical ceramics. His research aligns well with global priorities in energy efficiency, sensing technology, and photonics. While his work is highly innovative, future improvements could include increased international collaboration and participation in interdisciplinary projects that address emerging challenges in environmental sustainability or biomedical applications. Nonetheless, Dr. Lu’s achievements in materials science research are outstanding and well-documented. His leadership, creativity, and dedication make him a role model for younger researchers and a valuable contributor to scientific advancement. Given his qualifications and sustained excellence, Dr. Lu is not only suitable but highly deserving of recognition through a prestigious award such as the Best Innovator Award in Research. His continued contributions are likely to shape the future of ceramic materials and their applications across various industries.

Publications Top Notes

  • First Realization of Transparency of Polycrystalline SrZrO₃ Perovskite Ceramics: Insights into Structural, Optical, and Dielectric Performances
    Advanced Optical Materials, 2025
    Contributors: Jiadong Liu, Hailin Ren, Xiaomin Wang, Zhongbin Pan, Bin Lu

  • Insights into the Roles of the MgO Additive in Crystal Structures, Sintering Behaviors, and Optical Properties of Transparent In₂O₃ Semiconductor Ceramics
    Journal of Materials Chemistry C, 2024
    Contributors: Bo You, Bin Lu, Dazhen Wu, Ruijie Pei

  • Polycrystalline Magneto-Optical Transparent Pr₂Zr₂O₇ Pyrochlore Ceramic for Faraday Rotation
    Optics Letters, 2024
    Contributors: Youren Dong, Bin Lu, Liangbin Hu, Yongxing Liu, Shixun Dai

  • Removal of Deep Traps in Lu₂O₃:Tm Phosphors via Formation of Continuous Solid Solutions with In₂O₃ Enabling Widely Tailorable Bandgap Energy
    Advanced Powder Technology, 2024
    Contributors: Bin Lu, Hanchen Shen, Yun Shi, Jiang Li, Oleg Shichalin, Eugeniy Papynov, Xuejiao Wang

  • First Highly Transparent Gd₂Sn₂O₇ Pyrochlore Ceramics with High Refractive Index: Al₂O₃ Additive Roles on Structural Features, Sintering Behaviors, and Optical Performances
    Acta Materialia, 2024
    Contributors: Ruijie Pei, Bin Lu, Youren Dong, Bo You

  • Nickel Element Doping Impacts on Structure Features and Faraday Effects of Magneto‐Optical Transparent Holmium Oxide Ceramics
    International Journal of Applied Ceramic Technology, 2024
    Contributors: Mengyao Wang, Bin Lu, Bo You, Ruijie Pei, Zhigang Sun, Ji‐Guang Li, Yoshio Sakka, Naifeng Zhuang

  • Crystal Structural Effects on Up/Down-Conversion Luminescence Properties of GdInO₃:Tm,Yb Perovskite Phosphors for Effective Dual-Mode Anti-Counterfeit Applications
    Optics Express, 2024
    Contributors: Xiao-min Wang, Kai Feng, Liang Shan, Jie Zou, Bin Lu

  • Optical Grade (Gd₀.₉₅₋ₓLuₓEu₀.₀₅)₃Al₅O₁₂ Ceramics with Near-Zero Optical Loss: Effects of Lu³⁺ Doping on Structural Feature, Microstructure Evolution, and Far-Red Luminescence
    Journal of Advanced Ceramics, 2024
    Contributors: Zhigang Sun, Ji-Guang Li, Huiyu Qian, Yoshio Sakka, Tohru S. Suzuki, Bin Lu

  • The Effect of Lu³⁺ Doping on the Structural Stability and Luminescence Performances of Gd₃Al₅O₁₂:Dy Phosphors
    Metals, 2023
    Contributors: Huiyu Qian, Zhigang Sun, Tuanjie Liang, Mengyao Wang, Bin Lu, Hongbing Chen, Linwen Jiang

  • Production and Characterization of Highly Transparent Novel Magneto-Optical Ho₂Zr₂O₇ Ceramics with Anion-Deficient Fluorite Structures
    Journal of Materials Science & Technology, 2023
    Contributors: Liangbin Hu, Bin Lu, Bowen Xue, Shixun Dai

 

Lin Zhu | Materials Science | Best Researcher Award

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Assoc. Prof. Dr. Lin Zhu | Materials Science | Best Researcher Award

Teacher from Huazhong University of Science and Technology, China

Dr. Lin Zhu is an Associate Professor at the School of Physics, Huazhong University of Science and Technology (HUST) in Wuhan, China. Specializing in condensed matter physics, his research focuses on spintronics, molecular magnets, and low-dimensional materials. Dr. Zhu has made significant contributions to the design and understanding of multifunctional spintronic devices, exploring their electronic structures, magnetic properties, and transport phenomena. His work has been published in reputable journals, reflecting his commitment to advancing the field. With a strong academic background and a history of successful research projects, Dr. Zhu is recognized for his dedication to both scientific inquiry and education.

Professional Profile

Education

Dr. Lin Zhu’s academic journey began with a Bachelor’s degree in Applied Physics from Zhengzhou University in 1997. He then pursued a Master’s degree in Physics at Huazhong University of Science and Technology, completing it in 2001. Continuing at HUST, he earned his Ph.D. from the College of Optoelectronic Science and Engineering in 2005. This solid educational foundation laid the groundwork for his future research endeavors in condensed matter physics, particularly in the areas of spintronics and low-dimensional materials.

Professional Experience

Dr. Zhu commenced his professional career as a Lecturer at the School of Physics, HUST, serving from 2005 to 2013. During this period, he was involved in both teaching and research, contributing to the academic community. From 2011 to 2013, he expanded his research experience internationally as a Postdoctoral Associate at the Department of Physics, Virginia Commonwealth University in the United States. In 2013, he returned to HUST as an Associate Professor, a position he holds to date, where he continues to engage in advanced research and mentor students in the field of condensed matter physics.

Research Interests

Dr. Zhu’s research interests are centered around the design and mechanism study of multifunctional spintronic devices, the electronic structure and magnetic properties of molecular magnets, and the electrical, magnetic, and thermoelectric properties of low-dimensional materials. His work aims to understand and manipulate the spin-dependent transport properties in novel materials, contributing to the development of next-generation electronic devices. By exploring the fundamental aspects of these materials, Dr. Zhu seeks to uncover new physical phenomena and potential applications in the realm of condensed matter physics.

Research Skills

Dr. Zhu possesses a robust set of research skills, including proficiency in first-principles calculations, density functional theory, and various computational modeling techniques. His expertise extends to the synthesis and characterization of low-dimensional materials, as well as the analysis of their electronic and magnetic properties. Dr. Zhu’s ability to integrate theoretical and experimental approaches enables him to investigate complex physical systems effectively. His skills are instrumental in advancing the understanding of spintronic devices and molecular magnets, contributing valuable insights to the field.

Awards and Honors

Throughout his academic career, Dr. Zhu has received several accolades recognizing his research excellence. In December 2012, he was awarded the Outstanding Doctoral Dissertation Award in China, following a similar honor at the provincial level in Hubei in December 2011. His doctoral thesis was also recognized as an Excellent Degree Thesis by HUST in December 2009. In June 2007, he was named one of the Ten Research Elites among Ph.D. and Master’s students at HUST. Additionally, he received the Excellent Graduate Scholarship twice between 2005 and 2006, highlighting his consistent academic achievements.

Conclusion

Dr. Lin Zhu’s extensive research in condensed matter physics, particularly in spintronics and low-dimensional materials, underscores his suitability for recognition as a leading researcher. His academic background, international research experience, and numerous publications in high-impact journals reflect a career dedicated to scientific advancement. The honors he has received further attest to his contributions to the field. Dr. Zhu’s work not only enhances the understanding of complex physical systems but also paves the way for innovative applications in electronic devices, marking him as a distinguished figure in his area of expertise.

Publications Top Notes

  1. Title: High-Performance and Low-Power Sub-5 nm Field-Effect Transistors Based on the Isolated-Band Semiconductor
    Authors: Qu, Xinxin; Ai, Yu; Guo, Xiaohui; Zhu, Lin; Yang, Zhi
    Journal: ACS Applied Nano Materials
    Year: 2025

  2. Title: Corrigendum to “Study on the mechanism of enhancing photocurrent in TiS₂ photodetector by vacancy- and substitution-doping”
    Authors: Gu, Ziqiang; Xie, Xinshuo; Hao, Bin; Zhu, Lin
    Journal: Applied Surface Science (Erratum)
    Year: 2025

  3. Title: Study on the mechanism of enhancing photocurrent in TiS₂ photodetector by vacancy- and substitution-doping
    Authors: Gu, Ziqiang; Xie, Xinshuo; Hao, Bin; Zhu, Lin
    Journal: Applied Surface Science
    Year: 2025
    Citations: 2

  4. Title: Fully Electrically Controlled Low Resistance-Area Product and Enhanced Tunneling Magnetoresistance in the Van Der Waals Multiferroic Tunnel Junction
    Authors: Guo, Xiaohui; Zhang, Jia; Yao, Kailun; Zhu, Lin
    Journal: Advanced Functional Materials
    Year: 2025

  5. Title: Low-Power Transistors with Ideal p-type Ohmic Contacts Based on VS₂/WSe₂ van der Waals Heterostructures
    Authors: Cao, Zenglin; Zhu, Lin; Yao, Kailun
    Journal: ACS Applied Materials and Interfaces
    Year: 2024
    Citations: 3

  6. Title: NbS₂ Monolayers as Bipolar Magnetic Semiconductors for Multifunctional Spin Diodes and 3 nm Cold-Source Spin Field-Effect Transistors
    Authors: Qu, Xinxin; Guo, Xiaohui; Yao, Kailun; Zhu, Lin
    Journal: ACS Applied Nano Materials
    Year: 2024
    Citations: 3

 

Tieming Guo | Materials Science | Best Researcher Award

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Prof. Tieming Guo | Materials Science | Best Researcher Award

Professor from School of Materials Science and Engineering, Lanzhou University of Technology, China

Professor Tieming Guo is a distinguished faculty member at the Department of Metallic Materials Engineering, College of Materials Science and Engineering, Lanzhou University of Science and Technology, China. With a career dedicated to the in-depth study of corrosion behavior, microstructure, and metal matrix composite materials, he has made notable contributions to both fundamental science and industrial applications. His research on stainless steel corrosion, focusing on the effects of trace elements such as boron and cobalt, has provided steel manufacturers with theoretical foundations for material improvement. In recent years, his focus has expanded to high-strength, highly conductive copper matrix composites, further broadening his research scope. A standout example of his recent work involves laser cladding of Fe–0.3C–15Cr–1Ni alloy on martensitic stainless steel, optimizing wear and corrosion resistance by adjusting laser power parameters. Professor Guo’s research outcomes are characterized by rigorous experimentation, detailed microstructural characterization, and clear application-driven goals. His work is not only advancing scientific understanding but also offering practical solutions for the metallurgical industry. With a career that blends deep technical knowledge and applied research impact, Professor Guo stands out as a leader in his field and a strong candidate for recognition through research awards.

Professional Profile

Education

Professor Tieming Guo completed his higher education in materials science and engineering, specializing in metallic materials. He holds a Bachelor’s degree in Materials Science and Engineering, which laid the foundation for his early interest in the microstructure and corrosion behavior of metals. He then pursued a Master’s degree in Metallic Materials Engineering, where he focused on the effects of alloying elements on stainless steel performance. During his master’s studies, he began exploring the mechanisms behind stainless steel corrosion, particularly the role of microalloying with trace elements like boron and cobalt. Professor Guo completed his doctoral studies in Materials Science, focusing on metal matrix composites and advanced characterization techniques to study wear and corrosion properties. Throughout his academic training, he gained expertise in both theoretical modeling and practical experimentation, equipping him with a balanced perspective that integrates fundamental science with real-world applications. His academic background has positioned him well for a career that addresses both the challenges and opportunities in metallic materials research, particularly in areas directly relevant to industrial needs and technological development.

Professional Experience

Professor Tieming Guo has built a distinguished academic career as a faculty member at Lanzhou University of Science and Technology, where he serves as a professor and master’s tutor in the Department of Metallic Materials Engineering. Over the years, he has developed extensive experience in managing research projects related to stainless steel corrosion, microalloying, and metal matrix composites. He has been actively involved in supervising graduate students, guiding them through complex experimental work and analysis. His professional experience also includes collaborating with steel manufacturers, providing them with theoretical guidance and practical recommendations to improve material performance. Professor Guo has authored and co-authored numerous research papers, demonstrating his commitment to scientific dissemination and contribution to the broader materials science community. Additionally, he regularly participates in academic conferences and workshops, both as a speaker and attendee, ensuring that he remains at the forefront of emerging trends and technologies. His career trajectory showcases a strong combination of academic leadership, technical expertise, and industrial relevance, making him a well-rounded and impactful figure in the field of metallic materials engineering.

Research Interests

Professor Tieming Guo’s research interests center on the corrosion behavior of metallic materials, microstructure-property relationships, and the development of advanced metal matrix composites. He has a particular focus on stainless steel, studying how microalloying with trace elements like boron and cobalt influences corrosion resistance, wear performance, and mechanical properties. His work extends into exploring the effects of processing parameters, such as laser cladding techniques, on microstructure evolution and material performance. More recently, his research has branched into the study of high-strength, highly conductive copper matrix composites, reflecting his interest in combining mechanical robustness with superior electrical properties. Professor Guo is also deeply interested in the interplay between alloy composition, microstructural features (such as dendrite morphology and carbide distribution), and functional performance in aggressive environments. His commitment to advancing both theoretical understanding and practical applications ensures that his research remains highly relevant to both academic inquiry and industrial development, with an emphasis on improving material longevity, efficiency, and sustainability.

Research Skills

Professor Tieming Guo possesses a robust set of research skills that reflect his deep expertise in metallic materials engineering. He is highly skilled in experimental design, particularly in corrosion testing, wear resistance evaluation, and mechanical property characterization. His technical proficiency extends to advanced microstructural analysis techniques, including scanning electron microscopy (SEM), X-ray diffraction (XRD), and metallographic microscopy, allowing him to link microstructural features with macroscopic performance. Professor Guo is adept at working with laser cladding processes, optimizing operational parameters to achieve desired microstructural outcomes. He is also proficient in data analysis and interpretation, ensuring that experimental results are rigorously examined and connected to underlying material mechanisms. In addition to laboratory skills, Professor Guo has strong capabilities in research project management, student supervision, and academic writing, as demonstrated by his extensive publication record. His ability to integrate experimental work with theoretical insights enables him to address both fundamental scientific questions and practical engineering challenges, making his research outputs highly valuable to both academia and industry.

Awards and Honors

Throughout his career, Professor Tieming Guo has received recognition for his contributions to the field of materials science and engineering. He has been honored by academic institutions, professional societies, and industry partners for his impactful research on stainless steel corrosion and metal matrix composites. His awards reflect both the quality and relevance of his work, highlighting his ability to address critical challenges in metallic materials and translate research findings into practical recommendations. Professor Guo’s role as a master’s tutor and mentor has also earned him recognition for excellence in student supervision and academic leadership. He has been invited to present at national and international conferences, further underscoring his reputation as a respected expert in his field. While his achievements are already commendable, continuing to broaden his recognition through international awards, interdisciplinary collaborations, and participation in global research initiatives would further solidify his standing as a top-tier researcher.

Conclusion

Professor Tieming Guo stands out as a dedicated and impactful researcher whose work significantly advances the understanding of corrosion behavior, microalloying, and metal matrix composite development. His long-term commitment to both fundamental research and industrial application makes his contributions particularly valuable to the metallurgical field. With a strong academic background, extensive professional experience, and highly specialized research skills, Professor Guo has built a career marked by scientific rigor, practical relevance, and mentorship. His numerous awards and honors reflect the recognition he has earned within his field, although there is room to further elevate his profile through expanded international collaborations and broader dissemination of his work. Overall, Professor Guo is a highly deserving candidate for the Best Researcher Award, and his continued efforts promise to bring further advancements to materials science and engineering, benefiting both the academic community and industrial stakeholders.

Publications Top Notes

  1. Title: Characterization of stiff porous TiC fabricated by in-situ reaction of Ti with carbon derived from phenolic resin containing template
    Authors: Liu, Diqiang; Zhang, Hongqiang; Zhao, Weiqi; Jia, Jiangang; Guo, Tieming
    Journal: Journal of the European Ceramic Society
    Year: 2025

  2. Title: Effect of siliconizing temperature on microstructure and performance of alloy silicide layer on 347H stainless steel surface by melting salt non-electrolysis method
    Authors: Liu, Zehong; Guo, Tieming; Jia, Jiangang; Zhang, Ruihua; Yi, Xiangbin
    Journal: Surface and Coatings Technology
    Year: 2025

  3. Title: Fabrication and characterization of GCF/PyC composites by TG-CVI densified porous glassy carbon preform
    Authors: Jia, Jiangang; You, Xinya; Pan, Zikang; Liu, Diqiang; Guo, Tieming
    Journal: Ceramics International
    Year: 2025

  4. Title: Passivation characteristics and corrosion behavior of S32202 duplex stainless steel in different temperatures polluted phosphoric acid
    Authors: Yang, Haizhen; Guo, Tieming; Ouyang, Minghui; Zhao, Shuaijie; Liu, Zehong
    Journal: Surface and Coatings Technology
    Year: 2024
    Citations: 2

  5. Title: Comparative study on periodic immersion + infrared aging corrosion behavior of Q345qNH steel and Q420qNH steel in simulated industrial atmospheric environment medium
    Authors: Guo, Tieming; Yang, Haizhen; Wu, Weihong; Nan, Xueli; Hu, Yanwen
    Journal: Materialwissenschaft und Werkstofftechnik
    Year: 2024

Jinxian Feng | Materials Science | Best Researcher Award

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Dr. Jinxian Feng | Materials Science | Best Researcher Award

PhD Fellow at University of Macau, Macau

Dr. Jinxian Feng is a postdoctoral fellow in Applied Physics and Materials Engineering at the University of Macau. He earned his Ph.D. in 2023 from the same institution, following a B.Sc. in Chemistry from Sun Yat-sen University. His research focuses on the design and mechanism of high-efficiency catalysts for green energy conversion, including electrocatalysis and photoelectrochemical systems for water splitting, CO₂ reduction, and nitrogen fixation. Dr. Feng has published 16 peer-reviewed articles in high-impact journals such as Applied Catalysis B, Journal of Materials Chemistry A, and Chemical Engineering Journal. He has presented his work at several international conferences and received a Copper Award in the national “CCB Cup” energy-saving competition. His interdisciplinary collaborations and contributions to sustainable energy solutions reflect a strong commitment to addressing critical environmental challenges. As a rising talent in the field, Dr. Feng continues to advance innovative approaches for clean and renewable energy technologies.

Professional Profile

Education

Dr. Jinxian Feng has a solid academic background in chemistry and materials science, which forms the foundation of his research in green energy technologies. He obtained his Bachelor of Science degree in Chemistry from Sun Yat-sen University, Guangzhou, China, in 2015. This undergraduate training provided him with a strong grounding in fundamental chemical principles and laboratory techniques. Building on this, he pursued and successfully completed his Ph.D. in Applied Physics and Materials Engineering at the University of Macau in 2023. During his doctoral studies, Dr. Feng focused on the fabrication and mechanistic understanding of advanced electrocatalysts for sustainable energy applications, including CO₂ reduction and water electrolysis. His interdisciplinary education has equipped him with expertise in both theoretical and practical aspects of chemistry, materials science, and engineering, enabling him to conduct innovative research at the intersection of these fields. His academic journey reflects a continuous progression toward solving global energy and environmental challenges.

Professional Experience

Dr. Jinxian Feng has accumulated valuable professional experience in the field of materials science and energy research through his roles at the University of Macau. Following the completion of his Ph.D. in Applied Physics and Materials Engineering in 2023, he was appointed as a Research Assistant in the same department, where he contributed to various projects involving electrocatalysis and green energy conversion. Shortly after, he advanced to the position of Postdoctoral Fellow in October 2023, continuing his work on the development of high-performance catalysts for applications such as CO₂ reduction, nitrogen fixation, and water splitting. His professional experience includes collaboration with interdisciplinary teams, leading experimental design, and publishing high-quality research in top-tier journals. Dr. Feng’s work integrates both experimental and theoretical approaches to address energy and environmental challenges. His rapid progression from doctoral researcher to postdoctoral fellow reflects his dedication, competence, and growing impact in the field of sustainable energy technologies.

Research Interest

Dr. Jinxian Feng’s research interests lie at the forefront of sustainable energy conversion and storage technologies. His work focuses on the design, synthesis, and mechanistic study of advanced electrocatalysts and photocatalysts for critical reactions such as CO₂ reduction, nitrogen (N₂) fixation, water electrolysis, and biomass conversion. He is particularly interested in understanding the surface reconstruction and electronic properties of catalysts during reaction processes, aiming to enhance their activity, selectivity, and long-term stability. In addition to catalysis, Dr. Feng explores the development of photoelectrochemical devices, batteries, and supercapacitors, integrating materials engineering with electrochemical performance optimization. His interdisciplinary approach combines experimental techniques with theoretical insights to create efficient and scalable solutions for clean energy applications. By targeting fundamental challenges in green chemistry and materials science, Dr. Feng’s research contributes to the global pursuit of low-carbon technologies and provides valuable strategies for the development of next-generation energy systems.

Awards and Honors

Dr. Jinxian Feng has been recognized for his innovative contributions to sustainable energy research through awards and honors that highlight both his academic excellence and practical ingenuity. Notably, he received the Copper Award in the prestigious “CCB Cup” — the 16th National University Student Social Practice and Science Contest on Energy Saving and Emission Reduction, representing the Hong Kong, Macao, Taiwan, and International Group. This award was granted for his co-development of a smart solar moisture collection and power generation device, designed for intelligent flower maintenance, showcasing his creative approach to real-world energy challenges. This recognition not only reflects his ability to translate scientific knowledge into impactful applications but also underscores his commitment to addressing global environmental issues through innovative solutions. In addition to formal accolades, Dr. Feng’s continued publication in high-impact journals and participation in international conferences further illustrate the growing recognition of his contributions within the academic and scientific communities.

Research Skills

Dr. Jinxian Feng possesses a comprehensive set of research skills that span the fields of chemistry, materials science, and applied physics, with a strong emphasis on green energy technologies. He is highly skilled in the design and synthesis of nanomaterials for electrocatalysis and photocatalysis, including CO₂ reduction, nitrogen fixation, and water splitting. His expertise extends to advanced material characterization techniques such as XRD, SEM, TEM, and XPS, which he uses to analyze the structural and electronic properties of catalysts. Dr. Feng is also proficient in electrochemical testing methods, including linear sweep voltammetry (LSV), cyclic voltammetry (CV), and electrochemical impedance spectroscopy (EIS), enabling him to evaluate catalyst performance and reaction kinetics. Additionally, he applies computational tools and mechanistic analysis to study surface reconstruction and active sites, bridging theoretical insights with experimental results. His interdisciplinary research skills allow him to effectively tackle complex challenges in clean energy conversion and storage.

Conclusion

Jinxian Feng is a promising early-career researcher with a strong foundation in high-impact green energy research, a solid publication track record, and clear upward momentum. His current work and achievements are commendable and position him as a rising figure in materials and energy science.

However, he may be more suitable for an “Emerging Researcher” or “Young Investigator” award at this stage. For the Best Researcher Award, typically given to mid- or senior-level scientists with established independence, leadership in grants and labs, and sustained high-impact contributions, he might need a few more years to build that level of portfolio.

Publications Top Notes

  • Highly enhanced photocatalytic performance for CO₂ reduction on NH₂-MIL-125(Ti): The impact of (Cu, Mn) co-incorporation
    Separation and Purification Technology, 2025

  • Controllable Reconstruction of β-Bi₂O₃/Bi₂O₂CO₃ Composite for Highly Efficient and Durable Electrochemical CO₂ Conversion
    Nano Letters, 2025

  • Revealing the hydrogen bond network effect at the electrode-electrolyte interface during the hydrogen evolution reaction
    Journal of Materials Chemistry A, 2025

  • Electrodeposited Ternary Metal (Oxy)Hydroxide Achieves Highly Efficient Alkaline Water Electrolysis Over 1000 h Under Industrial Conditions
    Carbon Energy, 2025
    Citations: 0

  • Highly Dispersed Ru-Pt Heterogeneous Nanoparticles on Reduced Graphene Oxide for Efficient pH-Universal Hydrogen Evolution
    Advanced Functional Materials, 2024
    Citations: 9

  • In-situ Reconstruction of Catalyst in Electrocatalysis (Review)
    Journal not specified (Open Access), 2024
    Citations: 16

  • In Situ Reconstructed Cu/β-Co(OH)₂ Tandem Catalyst for Enhanced Nitrate Electroreduction to Ammonia in Ampere-Level
    Advanced Energy Materials, 2024
    Citations: 11

 

Zhiyong Dai | Materials Science | Best Researcher Award

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Assoc. Prof. Dr. Zhiyong Dai | Materials Science | Best Researcher Award

Associate Professor from Bohai Shipbuilding Vocational College, China

Zhiyong Dai is currently serving as an Associate Professor at Bohai Shipbuilding Vocational College, where he has made significant contributions in the field of materials science and engineering, particularly in welding and high-temperature resistant alloys. With a solid academic background culminating in a Doctorate in Materials Processing Engineering from Shenyang University of Technology (2024), he has combined theoretical knowledge with practical teaching and research experience. Over his academic and professional journey, Dr. Dai has been dedicated to both educational excellence and scientific inquiry. His teaching spans core courses in metallurgy, welding technology, and material properties. His research has produced impactful findings on the mechanical behavior and strengthening mechanisms of Inconel 625 and other advanced nickel-based alloys under extreme conditions. He has published in several high-impact journals, including Materials Science and Engineering A and Journal of Materials Research and Technology. His commitment to academic mentorship is evident from his active involvement in curriculum development and participation in student innovation projects. With a combination of applied industrial focus and strong academic contributions, Dr. Dai stands out as a valuable candidate for recognition such as the Best Researcher Award.

Professional Profile

Education

Zhiyong Dai has built a comprehensive and specialized educational foundation in the field of materials science and engineering. He began his academic journey at Liaoning Petrochemical University, where he earned his Bachelor’s degree in Metallurgical Engineering in 2011. He continued at the same institution to pursue a Master’s degree in Materials Science, which he completed in 2014. His growing interest in the advanced mechanical and physical properties of materials led him to enroll in a Ph.D. program in Materials Processing Engineering at Shenyang University of Technology, where he completed his doctorate in 2024. His doctoral research focused on the hot deformation behavior, strengthening mechanisms, and creep deformation of nickel-based alloys—particularly Inconel 625—under high-temperature conditions. This advanced academic training has equipped him with a deep understanding of metallurgical principles, material failure analysis, and solidification theory. The progression from undergraduate to doctoral studies shows a clear and consistent focus on developing both the theoretical and applied aspects of materials engineering, particularly in welding and high-temperature applications. Throughout his educational journey, Dr. Dai has also completed various professional development programs in higher education and has earned a certification as a university-level teacher from the Liaoning Provincial Department of Education.

Professional Experience

Dr. Zhiyong Dai has accumulated nearly a decade of teaching and research experience at Bohai Shipbuilding Vocational College, where he began his academic career in January 2015. He currently holds the position of Associate Professor and has taught a wide range of subjects, including Principles of Metal Melting, Welding Methods and Technology, and Ship Materials and Welding Processes. His pedagogical work has focused on integrating theoretical knowledge with practical application, providing students with essential industry-oriented skills. Beyond classroom instruction, he has played a pivotal role in guiding students through national and regional academic competitions, often earning accolades for both students and himself as a supervising instructor. His professional growth is marked by steady career progression, moving from Assistant Lecturer in 2015 to Lecturer in 2017, and being promoted to Associate Professor in 2024. Additionally, Dr. Dai has actively participated in academic research and curriculum development, contributing to several internal institutional projects focused on vocational training, modern apprenticeship models, and school-enterprise collaboration. This professional trajectory reflects a dedication to both teaching excellence and applied research, reinforcing his impact on vocational education and positioning him as a candidate deserving of national academic recognition.

Research Interests

Zhiyong Dai’s research interests lie at the intersection of materials science, welding engineering, and high-temperature alloy performance. He is particularly focused on the development and performance evaluation of nickel-based and nitrogen-containing alloys under extreme thermal and mechanical conditions. His recent studies have explored the creep deformation behavior, intermediate temperature brittleness, and tensile properties of Inconel 625 deposited metal and similar advanced materials. His work contributes valuable insights into the mechanisms that govern strength and failure in high-performance alloys used in aerospace, marine, and energy industries. Additionally, Dr. Dai is interested in improving welding materials and processes, especially those involving flux-cored wires and laser positioning devices. He also engages in educational research related to vocational training models and the development of innovation-driven talent in technical institutions. His combined focus on fundamental material behavior and applied welding techniques bridges the gap between theoretical research and industrial application. With a commitment to both scientific advancement and vocational education, his research is aligned with national priorities for high-end manufacturing and skilled labor development, further substantiating his suitability for prestigious research awards.

Research Skills

Dr. Zhiyong Dai possesses a diverse set of research skills that enable him to conduct comprehensive investigations into material behavior and welding technologies. He is adept in high-temperature mechanical testing, microstructural characterization, and metallurgical analysis, including creep testing and tensile strength evaluation of nickel-based alloys. His research utilizes both traditional metallographic methods and advanced analytical techniques to study deformation mechanisms, phase transformation, and grain structure evolution under various processing conditions. He also has practical experience in welding simulation, laser alignment tools, and arc welding systems, contributing to the development of innovative welding materials and methodologies. In addition to his laboratory skills, Dr. Dai is proficient in academic writing and technical reporting, with several Q1 and Q2 journal publications to his credit. He has also led or participated in funded research projects focused on modern apprenticeship systems and industry-academia collaboration. His ability to integrate experimental research with educational innovation showcases his multidisciplinary skill set. Furthermore, he is competent in the use of English for academic purposes, and has passed CET-4, demonstrating his capability to engage in international research communication.

Awards and Honors

Dr. Zhiyong Dai has received multiple recognitions throughout his professional career for both academic and instructional excellence. His awards span individual achievements, team leadership in competitions, and excellence in innovation. Notable honors include a First Prize in the Huludao City Natural Science Academic Achievement Awards in 2017, and a Third Prize for Technical Innovation in Laser Positioning Device Development in 2023. As a mentor, he earned the Instructor Award at the National Nonferrous Metal Vocational College Skills Competition (Aluminum Welding, 2017) and has guided students to success in events such as the “Challenge Cup” Liaoning Province Undergraduate Academic Science and Technology Competition. Additionally, he has received awards for educational guidance and technical paper writing, including third-place honors in faculty skills and student mental health initiatives. His consistent recognition over the years underscores his impact as an educator and researcher. His patent contributions on novel welding alloys and preparation methods also demonstrate his commitment to technological advancement. These achievements reflect his ability to balance academic rigor with applied technical expertise, making him a distinguished candidate for the Best Researcher Award.

Conclusion

In conclusion, Dr. Zhiyong Dai exemplifies the qualities of an outstanding researcher and educator in the field of materials science and engineering. His academic journey reflects a steady progression through increasingly specialized fields, culminating in high-impact research on high-temperature alloy performance and innovative welding technologies. With a strong portfolio of journal publications, patents, and successful research projects, he has demonstrated both depth and breadth in his scholarly contributions. Moreover, his extensive teaching experience and active involvement in student mentorship and academic competitions highlight his dedication to educational excellence. Dr. Dai’s work bridges the critical gap between theoretical material behavior and real-world industrial applications, aligning well with national goals for technological advancement and skilled workforce development. His recognition at local and national levels further attests to his professional competence and academic influence. Considering his contributions to scientific research, education, and innovation, Dr. Dai stands out as a compelling nominee for the Best Researcher Award. He has not only advanced the frontiers of his field but has also inspired the next generation of technical experts, making him a worthy recipient of this honor.

Publication Top Notes

  1. Study on creep properties and deformation mechanisms of novel nickel-based deposited metal
    Authors: Zhiyong Dai, Rongchun Wan, Yunhai Su, Yingdi Wang
    Journal: Advanced Engineering Materials
    Date: 2025-04-22
    DOI: 10.1002/adem.202500182
    Type: Journal Article

  2. Study on the tensile properties and deformation mechanism of high-temperature resistant nitrogen-containing nickel-based welding material deposited metal
    Authors: Zhiyong Dai, Yunhai Su, Yingdi Wang, Taisen Yang, Xuewei Liang
    Journal: Materials Science and Engineering: A
    Date: 2024-06
    DOI: 10.1016/j.msea.2024.146671
    Type: Journal Article

  3. Study of corrosion behavior of Inconel 625 cladding metal in KCl–MgCl₂ molten salt under isothermal and thermal cycling conditions
    Authors: Taisen Yang, Guiqing Zhang, Zhiyong Dai, Xuewei Liang, Yingdi Wang, Yunhai Su
    Journal: Journal of Materials Science
    Date: 2023-08
    DOI: 10.1007/s10853-023-08823-7
    Type: Journal Article

 

Kiran Batool | Materials Science | Best Researcher Award

Published on by Shen Awards

Dr. Kiran Batool | Materials Science | Best Researcher Award

Researcher from Physics Department, Pakistan

Dr. Kiran Batool is a dedicated researcher and academic specializing in nanomaterials, electrochemical energy storage, and environmental applications. With a robust research portfolio featuring 37 publications in high-impact journals, she has made significant contributions to material synthesis and characterization techniques. Her expertise extends to developing advanced materials for supercapacitors, batteries, and catalysts. Dr. Batool possesses strong teaching and mentorship experience, having instructed both undergraduate and graduate students in various physics courses. She has also served as a research associate, contributing to multiple interdisciplinary projects. Her commitment to innovation and sustainability drives her research in energy-efficient and environmentally friendly material applications. With a deep understanding of analytical and experimental techniques, she remains at the forefront of cutting-edge scientific advancements in her field.

Professional Profile

Education

Dr. Kiran Batool has pursued an extensive academic journey, equipping her with a strong foundation in physics and materials science. She completed her Ph.D. in Physics with a specialization in nanomaterials and energy storage applications. Prior to that, she earned an M.Phil. in Physics, focusing on advanced material characterization techniques. Her bachelor’s degree laid the groundwork for her expertise in fundamental physics and material properties. Throughout her academic career, she has remained engaged in research-intensive programs, allowing her to develop a deep understanding of electrochemical energy storage systems, catalysis, and sustainable materials. Her education has provided her with the theoretical knowledge and practical skills necessary to excel in both research and academia. Dr. Batool’s continuous pursuit of knowledge and innovation has made her a respected figure in the scientific community.

Professional Experience

Dr. Kiran Batool has accumulated extensive professional experience in both research and teaching roles. As a research associate, she contributed to various interdisciplinary projects focused on nanomaterial synthesis and energy storage applications. Her role involved conducting experimental research, analyzing data, and collaborating with fellow researchers to advance scientific knowledge. Additionally, Dr. Batool has served as a visiting lecturer, teaching undergraduate and graduate students in physics-related courses. She has supervised student research projects and provided mentorship to aspiring scientists. Her experience extends to laboratory management, experimental design, and technical troubleshooting. Dr. Batool’s dedication to education and research has enabled her to bridge the gap between theoretical knowledge and practical applications. Her contributions to academia and research institutions highlight her ability to work in dynamic environments while fostering scientific innovation.

Research Interests

Dr. Kiran Batool’s research interests lie in the development and characterization of advanced nanomaterials for energy and environmental applications. She is particularly focused on electrochemical energy storage systems, including supercapacitors and batteries, where she explores novel material compositions for enhanced performance. Her work also extends to catalysis, investigating sustainable materials for environmental remediation. Dr. Batool is deeply involved in the synthesis of nanostructured materials using techniques such as hydrothermal, sol-gel, and solvothermal methods. She is keen on integrating experimental and computational approaches to optimize material properties. Her research aims to contribute to the advancement of green energy solutions and environmentally friendly materials. By exploring innovative synthesis techniques and material functionalities, she seeks to develop next-generation energy storage devices that are both efficient and sustainable.

Research Skills

Dr. Kiran Batool possesses a diverse range of research skills that contribute to her excellence in material science and energy research. Her expertise includes nanomaterial synthesis through hydrothermal, sol-gel, and solvothermal techniques. She is proficient in material characterization methods such as X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), and Raman spectroscopy. Dr. Batool is also skilled in electrochemical analysis, including cyclic voltammetry and electrochemical impedance spectroscopy. Her ability to integrate various experimental techniques allows her to conduct in-depth analyses of material properties. Additionally, she has experience in data analysis, statistical modeling, and research project management. Her technical proficiency, combined with her strong analytical skills, enables her to conduct high-impact research that contributes to scientific advancements in energy storage and catalysis.

Awards and Honors

Dr. Kiran Batool has received multiple recognitions for her contributions to scientific research and academia. She has been acknowledged for her high-impact publications and significant advancements in nanomaterial synthesis and characterization. Her research on electrochemical energy storage has been cited extensively, highlighting its relevance in the field. Dr. Batool has also been honored for her teaching excellence, receiving commendations from academic institutions for her dedication to student mentorship and education. Additionally, she has participated in several international conferences and research symposiums, where her work has been recognized by peers and experts in the field. Her commitment to advancing scientific knowledge and her contributions to sustainable energy solutions continue to earn her accolades in the academic and research communities.

Conclusion

Dr. Kiran Batool stands out as a distinguished researcher and academic with a strong background in nanomaterials, energy storage, and material characterization. Her extensive research output, combined with her technical proficiency and teaching experience, makes her a valuable asset to the scientific community. She continues to push the boundaries of innovation, focusing on sustainable and efficient energy solutions. With expertise spanning experimental research, data analysis, and mentorship, she exemplifies excellence in academia and applied sciences. Dr. Batool’s dedication to research and education ensures that her contributions will have a lasting impact on the fields of material science and renewable energy. Her growing recognition and commitment to scientific progress make her a strong candidate for prestigious research awards and honors.

Publications Top Notes

  1. Sustainable Synthesis and Electrochemical Characterization of Ti₃C₂/Fe₁₋ₓBaₓCr₂O₄ Nanocomposite for Enhanced Supercapacitor Electrode Performance

    • Authors: Kiran Batool, Adel A. El-Marghany, Muhammad Usman Saeed
    • Year: 2025

  2. Bandgap Nature Transition and the Optical Properties of ABX₃ (A = K, Rb; B = Sr, Ba, Ca; X = Cl, Br, I) Perovskites Under Pressure

    • Authors: Mohib Ullah, Naqeeb Ullah, Ammar M. Tighezza, Kiran Batool, Ghulam M. Murtaza
    • Year: 2025
    • Citations: 2

  3. Electrifying Energy Storage by Investigating the Electrochemical Behavior of CoCr₂O₄/Graphene-Oxide Nanocomposite as Supercapacitor High-Performance Electrode Material

    • Authors: Rubia Shafique, Malika M. Rani, Naveed Kasuar Janjua, Mariam Akram, Akram A. Ibrahim
    • Year: 2024