Dr. Eman Shams | Innovative Leadership | Best Researcher Award 

Faculty of science, Alexandria University | Egypt

Author Profile

Scopus

Early Academic Pursuits

Dr. Eman F. Shams began her academic journey with a deep interest in inorganic and environmental chemistry, fields that inspired her to pursue higher studies at Alexandria University in Egypt. Her early education was shaped by a strong foundation in theoretical chemistry and laboratory practice, which later evolved into advanced research on metal-organic frameworks (MOFs), covalent organic frameworks (COFs), and zeolitic imidazolate frameworks (ZIFs). Through her doctoral studies, she gained expertise in designing porous materials for energy storage, catalysis, and gas separation. Her curiosity-driven approach to solving real-world problems, such as clean energy storage and environmental sustainability, defined her early academic direction. These formative years were characterized by persistence, interdisciplinary learning, and the development of a strong analytical mindset, which positioned her for significant contributions to both fundamental chemistry and applied technologies.

Professional Endeavors

Dr. Shams has established herself as an active researcher and educator across multiple international institutions. She has served as a visiting scholar, instructor, and postdoctoral researcher in Egypt, the United States, and Qatar, enriching her perspective on global scientific collaboration. Her teaching has included undergraduate and graduate-level instruction in chemistry, where she has focused on integrating cutting-edge research findings into classroom education. In addition, she has authored books on chemistry education, bridging the gap between complex scientific knowledge and accessible learning for students. Her professional endeavors extend beyond academia into collaborative projects with international research groups, where she has engaged in advanced studies on Fischer-Tropsch synthesis, gas-to-liquid (GTL) conversion, and innovative membrane technologies. Through these roles, she has demonstrated both versatility and leadership in adapting her expertise to diverse scientific and educational contexts.

Contributions and Research Focus

The core of Dr. Shams’ contributions lies in her innovative research on advanced materials. She has specialized in the design and application of MOFs, COFs, and ZIFs for use in energy storage, catalysis, and environmental remediation. Her projects include the development of sodium-ion battery electrode materials with enhanced conductivity, the reduction of carbon dioxide using Zr-based MOFs, and the creation of proton-conductive frameworks for fuel cell applications. Employing molecular dynamics (MD) and density functional theory (DFT) simulations, she has provided fundamental insights into proton migration, de-intercalation processes, and material performance optimization. Beyond theoretical modeling, she has also contributed to applied chemistry by developing hollow fiber systems and membranes for energy and environmental applications. Her research embodies the convergence of fundamental science and practical innovation, with clear implications for sustainable energy technologies and climate change mitigation.

Accolades and Recognition

Dr. Shams has been recognized with multiple awards for her research, teaching excellence, and contributions to the chemistry community. She has received honors for her innovative teaching practices, her ability to inspire students, and her impactful research on advanced materials. Her work has been published in leading journals such as the International Journal of Hydrogen Energy, Discover Materials, European Journal of Inorganic Chemistry, and the Journal of Molecular Structure. She also serves as an editor and reviewer for respected international journals, further validating her expertise and leadership in the scientific community. Invitations to review manuscripts and join editorial boards highlight the esteem in which her peers hold her. These accolades not only celebrate her past achievements but also underscore her continuing influence as a chemist dedicated to advancing both knowledge and practice.

Impact and Influence

The impact of Dr. Shams’ research extends well beyond academia. Her studies on MOFs and COFs contribute directly to addressing global challenges such as clean energy storage, efficient catalysis, and carbon capture. Her findings provide pathways toward sustainable energy technologies, influencing both academic research and industrial applications. By mentoring students and collaborating internationally, she has contributed to the development of young researchers and fostered cross-border scientific exchange. Her publications are widely cited by scholars in the United States, Europe, and the Middle East, demonstrating her influence on global research agendas. Moreover, her interdisciplinary approach to chemistry—combining computational modeling, materials synthesis, and practical application—positions her as a leader capable of shaping future directions in energy and environmental solutions.

Legacy and Future Contributions

Looking ahead, Dr. Shams is poised to leave a lasting legacy in chemistry through her innovative work at the intersection of materials science and sustainable technologies. Her research trajectory suggests future breakthroughs in the design of functional porous materials for batteries, catalysis, and fuel cells. With a commitment to addressing climate change and promoting energy efficiency, she is expected to contribute further to the development of renewable energy solutions. Beyond her laboratory achievements, her continued dedication to teaching, mentoring, and publishing will ensure that her influence is felt across generations of chemists and engineers. Her legacy will be characterized by her ability to bridge fundamental chemistry with global sustainability goals, providing a blueprint for how scientific research can transform society.

Notable Publications

The dance of sodium: de-intercalation voltage in metal-organic frameworks