Moritz Rosenthal | Electrochemistry | Research Excellence Award 

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Mr. Moritz Rosenthal | Electrochemistry | Research Excellence Award 

Aalto University | Finland

Mr. Moritz Rosenthal is a dedicated chemist and doctoral candidate at Aalto University School of Chemical Engineering, Finland, with a strong focus on material and nano chemistry. He earned his M.Sc. in Chemistry from Leibniz University, Hanover, with distinction, emphasizing advanced inorganic, physical, and analytical chemistry, and his B.Sc. in Chemistry from the same institution, graduating with a solid foundation in synthesis and characterization of materials, including transition metal seleno phosphates. His professional journey includes research assistant roles at both Leibniz University and Aalto University, where he synthesized and analyzed catalysts for oxygen evolution reactions in acidic electrolytes, targeting sustainable replacements for platinum group metals in proton exchange membrane electrolyzers. During his Master’s thesis, he collaborated internationally with experts on advanced material studies, and his industrial internship at Honeywell Specialty Chemicals led to a patented invention related to low-melting flux materials. His research interests encompass catalysis, electrochemistry, transition metal oxides, and sustainable hydrogen technologies. Mr. Rosenthal has consistently demonstrated academic excellence, innovative research contributions, and a commitment to advancing clean energy solutions. His work bridges fundamental chemistry and applied materials science, reflecting both scholarly rigor and practical impact in the field of sustainable energy and advanced functional materials.

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Featured Publications

Zhongmin Zhou | Solar Cells | Research Excellence Award

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Prof. Zhongmin Zhou | Solar Cells | Research Excellence Award

Qingdao University of Science and Technology | China

Prof. Zhongmin Zhou is a Professor at Qingdao University of Science and Technology and a leading researcher in the field of new energy materials, with a strong focus on high-performance perovskite solar cells. He received his Bachelor’s, Master’s, and Doctoral degrees from Qingdao University of Science and Technology and the Institute of Chemistry, Chinese Academy of Sciences, respectively, building a solid foundation in materials chemistry and device physics. Following his doctorate, he undertook postdoctoral research at the Qingdao Institute of Bioenergy and Bioprocess Technology (CAS), the National Institute for Materials Science, and The University of Tokyo, gaining extensive international research experience in advanced functional materials. Since joining Qingdao University of Science and Technology, he has been actively engaged in molecular design and device engineering to enhance the efficiency, stability, and scalability of perovskite photovoltaic devices. His research outcomes have been widely recognized through publications in top-tier journals such as Nature Photonics, Nature Communications, JACS, Angewandte Chemie, and Advanced Materials, accumulating over 5,000 citations. He has received multiple academic honors and competitive research awards for his innovative contributions. Overall, Prof. Zhou’s work significantly advances next-generation solar energy technologies and supports the global transition toward sustainable energy solutions.

Profile: Scopus

Featured Publications

Ion-Mediated Self-Healing Strategy Enabling Efficient and Stable ETL-Free Perovskite Solar Cells
Angewandte Chemie International Edition, 2025
Additive Engineering Toward Suppression of Sn2+ Oxidation in Sn–Pb Perovskite Solar Cells: Mechanisms, Advances, and Outlook
– Review Article, 2025
Ion-Migration-Induced Dual Interface Dipoles for High-Performance Perovskite Solar Cells
Matter, 2025
Competitive-Coordination-Induced Crystallization Regulation for Efficient and Stable Sn–Pb Perovskite Solar Cells
Angewandte Chemie International Edition, 2025
Substituent Adjustment Strategy on Modifying Perovskite/Spiro-OMeTAD Interface in Perovskite Solar Cells
Chemical Engineering Journal, 2025

Mr. Sam Grose | Chemical Engineering | Research Excellence Award

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Mr. Sam Grose | Chemical Engineering | Research Excellence Award

Kampala International University | Uganda

Mr. Sam Grose is an emerging researcher whose work spans renewable energy, energy engineering, bioenergy, electrical engineering, and applied geology, with a growing focus on sustainable power systems in developing regions. He is pursuing a Master’s degree in Renewable Energy at Kampala International University, building upon a strong academic foundation that includes a Bachelor’s degree in Geology, IT Network Engineering studies, and technical training in computer science and electronics. His research experience includes analyzing the performance of Integrated Gasification Combined Cycle (IGCC) systems for solid waste–based electricity generation and evaluating the geomorphological impacts of saw-milling activities on landforms in Liberia. Professionally, he has contributed to the Liberia Petroleum Regulatory Authority as a Research Assistant and Intern-Geologist, where he supported petroleum regulatory data management, geological analysis, and report development. Additionally, he has worked as a science writer producing articles on geology and renewable energy and has held roles in national electoral processes, demonstrating leadership and public service engagement. His awards include a 50% tuition scholarship for his M.Sc. studies and sponsorship support from the Liberia Petroleum Regulatory Authority. Through his interdisciplinary expertise, Sam is committed to advancing sustainable energy solutions and contributing to environmentally responsible development.

Profiles: Orcid | Google Scholar

Featured Publications

Grose, S. O., Abdulkarim, A., Eze, V. H. U., Sanusi, Y. (2025). An overview of methods and future research directions on the conversion of solid waste through biomass cogeneration and pyrolysis for electrical power generation. Discover Electronics.

Dr. Iheke Michael Nwachukwu | Electrochemical Energy Storage System | Best Review Paper Award

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Dr. Iheke Michael Nwachukwu | Electrochemical Energy Storage System | Best Review Paper Award

National Open University of Nigeria, Abuja | Nigeria

Dr. Iheke Michael Nwachukwu is a motivated research scientist and university lecturer specializing in nanostructured metal oxides, energy-saving and conversion devices, and lithium-ion batteries with carbon nanocomposites. He holds a PhD in Solar Energy Physics (2023), an M.Sc in Solar Energy Physics (2016), and a B.Sc in Physics (2010) from the University of Nigeria. Dr. Nwachukwu has extensive experience in designing experiments, synthesizing and characterizing nanomaterials for supercapacitors and Li-ion battery applications, contributing to several journal publications and submissions. His expertise extends to renewable energy assessment, understanding environmental impacts, and translating scientific insights into practical applications. Skilled in SEM/EDX, TEM, AFM, XRD, UV-Vis, and electrochemical techniques including EIS and CV, he combines hands-on technical knowledge with strong research analysis, problem-solving, and communication abilities. In addition to research, he serves as Assistant Departmental Examination Officer, Faculty Representative to the Academic Board, and Departmental Physics Practical Coordinator at the National Open University of Nigeria. Recognized for his contributions to nanotechnology and energy research, he was awarded 2nd Best Poster Presenter at the 4th African Conference on Nanotechnology Applications (2021) and serves on the Editorial Board of the International Chemistry Scientist Awards (2024). Dr. Nwachukwu continues to advance sustainable energy solutions through innovative research and academic leadership.

Profiles: Scopus | Orcid | Google Scholar

Featured Publications

Inyang, E., Ekechukwu, C., Nwachukwu, I., Thompson, E., William, E., & Lawal, K. (2025). Non-relativistic Solutions of the modified Hylleraas potential in the presence of external magnetic and Aharonov-Bohm flux fields for heteronuclear diatomic molecules. Physical Sciences and Technology.

Inyang, E.P., Nwachukwu, I.M., Ekechukwu, C.C., Ekong, I.B., William, E.S., Lawal, K.M., Simon, J., Momoh, K.O., & Oyelami, O.A. (2024). Analytical solution of the class of inversely quadratic Yukawa potential with application to quantum mechanical systems. Eurasian Physical Technical Journal.

Nwachukwu, I.M., Nwanya, A.C., Ekwealor, A.B.C., & Ezema, F.I. (2024). The potentials of LiMnPO4 cathode material for aqueous Li-ion batteries: An investigation into solid state and green chemistry approaches. Applied Surface Science Advances.

Ngongang, R.T., Nwanya, A.C., Onoh, E.U., Nwachukwu, I.M., Ugwuoke, C., Atawa, B., Ottou Abe, M.T., Ndjaka, J.-M.B., & Ezema, F.I. (2023). Studies of the dielectric properties of PVDF-CaCu3Ti4O12 composite thin film: Experimental and theoretical. SSRN Preprint.

Nwachukwu, I.M., Nwanya, A.C., Ekwealor, A.B.C., & Ezema, F.I. (2023). Research progress in solid-state synthesized LiMnPO4 cathode material for Li-ion battery applications. Applied Surface Science Advances.

Nwachukwu, I.M., Nwanya, A.C., Alshoaibi, A., Awada, C., Ekwealor, A.B.C., & Ezema, F.I. (2023). Recent progress in green synthesized transition metal-based oxides in LIBs as energy storage devices. Current Opinion in Electrochemistry.

Nwachukwu, I.M., & Nwanya, A.C. (2022). Recent progress in Mn and Fe-rich cathode materials used in Li-ion batteries. Journal of Energy Storage.

Dr. Mohammad Barati | Modeling | Best Researcher Award

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Dr. Mohammad Barati | Modeling | Best Researcher Award

University of Kashan | Iran

Dr. Mohammad Barati is an accomplished researcher and assistant professor in applied chemistry at the University of Kashan. He earned his Ph.D. in Applied Chemistry from the University of Tehran, following an M.Sc. and B.Sc. in Applied Chemistry from the University of Tabriz. Dr. Barati has extensive research experience in renewable energy and nanotechnology, focusing on the conversion of microalgae into biodiesel and bio-jet fuel using supercritical media, simultaneous bio-diesel and hydrogen production, and the development of polymer nanocomposites for drug delivery and bio-applications. His work also encompasses the synthesis and performance evaluation of magnetic polymer nanocomposites and their use as scaffolds in cell culture. Recognized for his excellence in teaching, he has been ranked first in annual faculty teaching evaluations at the University of Kashan and has received awards including the provincial first prize for university startups and the second-rank award at the Sabzkooh National Technology Festival. Dr. Barati’s research contributes significantly to sustainable energy, biofuel production, and advanced polymer materials, reflecting his dedication to both scientific innovation and academic excellence.

Profiles: Scopus | Orcid | Google Scholar

Featured Publications

Fanaee, G., Barati, M., & Bashiri, H. (2026). “Process optimization, kinetics, thermodynamics and kinetic Monte Carlo modeling of catalyzed biodiesel production in supercritical medium” in Renewable Energy.

Aghilinategh, M., Barati, M., & Hamadanian, M. (2024). “Supercritical microalgae conversion to biofuel and value‐added components (oxygenates, hydrocarbons, and aromatics): A catalyst characterization study” in Environmental Progress & Sustainable Energy.

Alirezaei Alavije, A., Barati, F., Barati, M., Nazari, H., & Karimi, I. (2021). “Polyethersulfone/MWCNT nanocomposite scaffold for endometrial cell culture: preparation, characterization, and in vitro investigation” in Biomedical Physics & Engineering Express.

Barati, M. (2019). “Nanobiocatalytic processes for producing biodiesel from algae” in Sustainable Bioenergy (Book chapter).

Alirezaie Alavijeh, A., Barati, M., Barati, M., & Abbasi Dehkordi, H. (2019). “The potential of magnetic nanoparticles for diagnosis and treatment of cancer based on body magnetic field and organ-on-the-chip” in Advanced Pharmaceutical Bulletin.

Mirzaie, Z., Reisi-Vanani, A., & Barati, M. (2019). “Polyvinyl alcohol-sodium alginate blend, composited with 3D-graphene oxide as a controlled release system for curcumin” in Journal of Drug Delivery Science and Technology.