Melese Asfaw | Petroleum Engineering | Best Researcher Award

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Mr. Melese Asfaw | Petroleum Engineering | Best Researcher Award

Lecturer at Mekdela Amba University | Ethiopia

Mr. Melese Damtew Asfaw is a distinguished Ethiopian academic and researcher whose work bridges analytical chemistry, environmental science, and natural product studies. As a lecturer and postgraduate research coordinator at Mekdela Amba University, he has demonstrated a profound commitment to advancing education, research, and community engagement. His research focuses on analytical method development, environmental and biological sample analysis, and the exploration of bioactive compounds from natural sources for public health and environmental protection. He has published extensively in international journals on topics such as essential oil extraction, biodiesel production, phytochemical analysis, and water quality assessment, reflecting his expertise in both theoretical and applied chemistry. Beyond his scholarly contributions, he has played key leadership roles within academic and research committees, guiding curriculum development and research policy formation. His mentorship of undergraduate and postgraduate students underscores his dedication to scientific capacity-building. Melese’s interdisciplinary research has been supported by several national grants addressing sustainable agriculture, renewable energy, biodiversity, and environmental monitoring. His participation in numerous conferences and journal reviewing activities further highlights his engagement with the global scientific community. Known for his professionalism, innovation, and commitment to societal impact, he integrates chemistry with sustainability principles to address Ethiopia’s environmental and developmental challenges. Through his continuous pursuit of excellence, Melese Damtew Asfaw stands as an exemplary scholar contributing to the advancement of science and the empowerment of future generations.

Profile: Google Scholar

Featured Publications

Asfaw, M. D. (2022). Effects of animal manures on growth and yield of maize (Zea mays L.).

Asfaw, M. D. (2022). Review on watermelon production and nutritional value in Ethiopia.

Damtew, M. (2022). A review on chemical composition, medicinal value and other applications of Azadirachta indica.

Asfaw, M. D. (2022). Basic essential oil extraction techniques and procedures from aromatic plants

Asfaw, M. D. (2022). Chemical composition of olive stems essential oil from Ethiopia.

Rabia Ahmad | Petroleum Engineering | Best Researcher Award

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Dr. Rabia Ahmad | Petroleum Engineering | Best Researcher Award

Post-Doctoral Research Fellow at King Fahd University of Petroleum and Minerals (KFUPM), Dharan, Saudi Arabia

Rabia Ahmad is a dedicated postdoctoral research fellow at King Fahd University of Petroleum and Minerals, where she explores cutting-edge materials for sustainable energy solutions. Her academic and professional journey reflects a consistent commitment to research excellence in electrochemistry, energy storage, and nanomaterials. She has held diverse roles, including research associate and exchange scholar, gaining experience across Pakistan, the United States, and Saudi Arabia. Rabia has developed an impressive profile through interdisciplinary collaborations and innovation-driven research. Her expertise lies in the synthesis and characterization of novel materials that enhance the efficiency of batteries, supercapacitors, and electro-catalytic systems.

Profile

Google Scholar

Education

Rabia Ahmad holds a Ph.D. in Energy Systems Engineering from the U.S.-Pakistan Center for Advanced Studies in Energy, completed in 2022 at the National University of Sciences and Technology (NUST), Islamabad. Her doctoral work focused on advanced electrochemical materials, particularly for energy storage devices. She previously earned an M.Phil. in Chemistry from Gomal University in 2016, following a Master of Chemistry from Baha Uddin Zakariya University in 2008. Her academic foundation was laid with a Bachelor of Science from Government Degree College for Women, affiliated with BZU. This educational trajectory empowered her with theoretical and practical grounding in materials science.

Experience

Rabia Ahmad brings extensive multidisciplinary experience in materials chemistry and electrochemical systems. She currently serves as a postdoctoral fellow at KFUPM, working on aluminum-air batteries and petroleum coke-derived carbon for electrocatalysis. Previously, she was a research associate at NUST, contributing to electric vehicle components, LFP electrode development, and MOF-based catalysts. Her tenure as a research exchange scholar at Indiana University–Purdue University Indianapolis enriched her expertise in MXene composites. From 2017–2021, she served as a research assistant at NUST, mentoring students and conducting lab demonstrations. Her career reflects a continual focus on sustainable and scalable energy materials.

Research Interest

Rabia Ahmad’s research interests span energy materials and electrochemical systems, with a focus on Metal Organic Frameworks (MOFs), MXenes, nanoporous carbon electrodes, and petroleum coke derivatives. She is particularly invested in the development of hybrid supercapacitors, lithium-ion batteries (LIBs), and metal-air batteries with improved efficiency and sustainability. Her work extends into ORR/OER catalysis and advanced electrochemical characterizations such as cyclic voltammetry and impedance spectroscopy. Her scientific curiosity also includes the synthesis of nanomaterials such as graphene oxide and metal sulfides. Her interdisciplinary approach integrates green chemistry with material innovation for next-generation energy devices.

Awards

Rabia Ahmad has received several accolades recognizing her contributions to energy research. In 2025, she won a Paper Presentation Award at The Electrochemical Society’s 247th Meeting for her work on hybrid capacitors using MXene-CNT composites. Earlier, in 2024, she was honored at the American Chemical Society Fall Conference for presenting on vacuum residue for electrocatalysis. She received a Best Poster Award at PU-AESM-2019 and was a lab demonstrator in multiple workshops at NUST. She also completed a prestigious M-Xene course at Drexel University in 2021 and was a USAID merit scholar during her Ph.D. studies. These honors underscore her excellence and impact.

Publications Top Notes

Rabia Ahmad has authored several influential papers in top-tier journals, contributing significantly to energy materials research:

  1. Effect of barbituric acid in regulating the Al anode/electrolyte interface – Journal of Power Sources, 2025.

  2. Influence of Mechanochemical Processing on Petroleum Coke – Journal of Industrial and Engineering Chemistry, 2025.

  3. Enhanced redox kinetics in ceria-doped MOFs – Journal of Industrial and Engineering Chemistry, 2025, explores supercapacitor electrodes.

  4. Harnessing M-Xenes for hydrogen storage – Renewable and Sustainable Energy Reviews, 2025, widely cited in green hydrogen discussions.

  5. Manganese-doped Ni-MOF catalysts for metal-air batteries – Materials Chemistry and Physics, 2025.

  6. Sustainable additives for Aluminium corrosion control – Journal of Electroanalytical Chemistry, 2025.

  7. M-Xenes and electrochemical reduction reactions – Chemical Engineering Journal, 2025, outlining new frontiers in M-Xene chemistry.

Conclusion

Rabia Ahmad is a rising leader in the energy materials research community. Her academic rigor, global collaborations, and impactful contributions to the field of electrochemical energy storage set her apart. Her work not only advances scientific understanding but also aligns with global sustainability goals through green energy innovations. Through high-impact publications, patents, and award-winning presentations, she has demonstrated her capacity for transformative research. As she continues her postdoctoral work on aluminum-air batteries and sustainable electro-catalysts, Rabia remains committed to pushing the frontiers of material science for a cleaner and more efficient energy future.