Enno Wagner | Thermodynamics | Excellence in Research Award

Published on by Research Chemistry Awards

Prof. Dr. Enno Wagner | Thermodynamics | Excellence in Research Award

Frankfurt University of Applied Sciences, Germany

Prof. Dr. Enno Wagner is a distinguished academic and engineering expert whose career spans mechatronic design, hydrogen systems, and advanced energy technologies. He earned his mechanical engineering degree with a specialization in energy technology from the Technical University of Darmstadt, where he later completed a doctoral thesis in technical thermodynamics focusing on heat and mass transport and high-resolution measurement techniques. His professional journey includes impactful roles at renowned organizations such as the Fraunhofer ISE, EVONIK Degussa, Stiebel Eltron, and the Schunk Group, where he led multidisciplinary teams in product design, automation, electronics, and control technology. Since 2019, he has served as Professor for Mechatronic Design and Engineering Mechanics at the Frankfurt University of Applied Sciences, directing the Mechatronics bachelor program, teaching engineering design and hydrogen technologies, and leading the hydrogen technology laboratory. His research interests center on alkaline water electrolysis, entropy analysis using bubble dynamics, and compact hydrogen storage solutions, contributing significantly to the broader field of sustainable energy systems. Recognized for his scientific contributions, leadership, and innovation in fuel cell and hydrogen research, he continues to advance cutting-edge knowledge and inspire future engineers through his academic and research endeavors.

Profiles: Scopus | Orcid | Google Scholar

Featured Publications

Wagner, E., Delp, E., & Mishra, R. (2023). “Energy storage with highly-efficient electrolysis and fuel cells: Experimental evaluation of bifunctional catalyst structures” in Topics in Catalysis.

Wagner, E., & Kohnke, H.-J. (2020). “Another chance for classic AFCs? Experimental investigation of a cost-efficient unitized regenerative alkaline fuel cell using platinum-free gas diffusion electrodes” in Fuel Cells.

Wagner, E. (2018). “Betrachtung von Nachhaltigkeit und Umweltverträglichkeit mithilfe des neuen Syntropie-Index” in Ökologisches Wirtschaften.

Wagner, E. (2009). “Hochauflösende Messungen beim Blasensieden von Reinstoffen und binären Gemischen” (Doctoral Dissertation, Deutsche Nationalbibliothek).

Wagner, E., & Stephan, P. (2009). “High-resolution measurements at nucleate boiling of pure FC-84 and FC-3284 and its binary mixtures” in Journal of Heat Transfer.

Wagner, E., Sodtke, C., Schweizer, N., & Stephan, P. (2006). “Experimental study of nucleate boiling heat transfer under low gravity conditions using TLCs for high-resolution temperature measurements” in Heat and Mass Transfer.

Wittstadt, U., Wagner, E., & Jungmann, T. (2005). “Membrane electrode assemblies for unitised regenerative polymer electrolyte fuel cells” in Journal of Power Sources.

Mr. Ahmaa Abuhaiba | Thermodynamics | Best Researcher Award

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Mr. Ahmaa Abuhaiba | Thermodynamics | Best Researcher Award

West London Institute of Technology, Uxbridge College | United Kingdom

Mr. Ahmad Abuhaiba is a dedicated mechanical engineer and academic with strong expertise in turbomachinery, energy systems, and power electronics. He holds a Master of Philosophy in Mechanical Engineering from City St George’s, University of London, a Bachelor’s degree in Mechanical Engineering from the Islamic University of Gaza, and completed an exchange programme at the University of Glasgow. He also earned an Award in Education and Training from City & Guilds. Currently serving as a Lecturer in Mechanical Engineering at Uxbridge College, London, he delivers higher education courses in mechanical and energy systems while managing workshops and leading practical, project-based learning. His prior experience includes academic and research roles at London Premier Centre, City St George’s University of London, Stavanger University, and the University of Birmingham. His research focuses on micro-gas turbines, silicon-carbide power converters, energy efficiency, and sustainable power systems. He has published peer-reviewed work on microturbine design and performance enhancement. Ahmad’s teaching philosophy integrates research-led learning with practical engineering applications. His academic achievements and dedication to advancing clean energy technologies reflect his commitment to innovation and engineering excellence.

Profile: Orcid

Featured Publications

Ahmad Abuhaiba (2025). “Reducing Greenhouse Gas Emissions from Micro Gas Turbines Using Silicon Carbide Switches.” Methane.

Ahmad Abuhaiba (2025). “Size Reduction in Micro Gas Turbines Using Silicon Carbide.” Gases.

Ahmad Abuhaiba (2025). “Size Reduction in Micro Gas Turbines Using Silicon Carbide.” Preprints.

Ahmad Abuhaiba, Mohsen Assadi, Dimitra Apostolopoulou, Jafar Al-Zaili, & Abdulnaser I. Sayma (2023). “Power Transmission and Control in Microturbines’ Electronics: A Review.” Energies

Prof. Dr. K. Yamuna Rani | Chemical Engineering | Best Researcher Award

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Prof. Dr. K. Yamuna Rani | Chemical Engineering | Best Researcher Award

CSIR-Indian Institute of Chemical Technology | India

Prof. Dr. K. Yamuna Rani is a distinguished chemical engineering professional whose academic journey reflects consistent excellence and innovation. She earned her B.Tech. in Chemical Engineering from Osmania University with distinction, followed by an M.Tech. in Process Control from IIT Madras, where she secured the first rank and was awarded the prestigious Dr. Subba Raju Memorial Medal. She later completed her Ph.D. at IIT Madras, focusing on the optimization and control of semi-batch processes using artificial neural networks. With an illustrious career spanning over three decades at CSIR-Indian Institute of Chemical Technology, she has advanced through progressive scientific leadership roles, from Scientist B to Chief Scientist and Chair. Her research interests lie in process control, optimization, artificial neural networks, and plantwide control design, contributing significantly to both fundamental and applied aspects of chemical engineering. She has been recognized with numerous honors, including the CSIR Young Scientist Award, Kuloor Memorial Award, DAAD Fellowship, Distinguished Professional Accomplisher Award (IIChE HRC Chemical Ratna), and fellowships from prestigious professional bodies. She also serves as an editor and reviewer for reputed journals, highlighting her academic influence. Prof. Rani’s career epitomizes excellence, dedication, and leadership, making her a trailblazer and inspiration in the field of chemical engineering.

Profile: Google Scholar

Featured Publications

Viswanath, D. S. (2007). Viscosity of liquids: Theory, estimation, experiment, and data. Springer Verlag.

Sarmah, N., Revathi, D., Sheelu, G., Rani, K. Y., Sridhar, S., Mehtab, V., & Sumana, C. (2018). Recent advances on sources and industrial applications of lipases. Biotechnology Progress

Prasad, N. S., Moulik, S., Bohra, S., Rani, K. Y., & Sridhar, S. (2016). Solvent resistant chitosan/poly (ether-block-amide) composite membranes for pervaporation of n-methyl-2-pyrrolidone/water mixtures. Carbohydrate Polymers

Alam, S., Kumar, J. P., Rani, K. Y., & Sumana, C. (2017). Self-sustained process scheme for high purity hydrogen production using sorption enhanced steam methane reforming coupled with chemical looping combustion. Journal of Cleaner Production

Rani, K. Y., & Gangiah, K. (1991). Adaptive generic model control: Dual composition control of distillation. AIChE Journal

Sunitha, K., Rani, K. Y., Moulik, S., Satyanarayana, S. V., & Sridhar, S. (2013). Separation of NMP/water mixtures by nanocomposite PEBA membrane: Part I. Membrane synthesis, characterization and pervaporation performance. Desalination

Kamesh, R., & Rani, K. Y. (2016). Novel formulation of adaptive MPC as EKF using ANN model: Multiproduct semibatch polymerization reactor case study. IEEE Transactions on Neural Networks and Learning Systems