Dr. Mawuse Amedzo-Adore is an Energy Materials Engineer with a Ph.D. in Energy and Materials Engineering from Dongguk University, South Korea. His research expertise includes the design, synthesis, and characterization of nanomaterials for energy-conversion systems, particularly focusing on lithium and sodium rechargeable batteries and supercapacitors. Dr. Amedzo-Adore has held positions such as Postdoctoral Research Fellow and Visiting Graduate Student Researcher, where he contributed to the development of materials for energy storage systems and supervised graduate student research. He has published multiple articles in reputable journals and presented his work at international conferences, showcasing his proficiency in material synthesis, electrode fabrication, and electrochemical testing. With a strong background in collaborative research, he is committed to advancing innovations in energy materials.
Professional Profile:
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Suitability Summary for Mawuse Amedzo-Adore, Ph.D. for the Best Researcher Award
Dr. Mawuse Amedzo-Adore’s comprehensive expertise in energy materials, demonstrated research capabilities, impressive publication record, and dedication to collaboration and mentorship make him an exemplary candidate for the Best Researcher Award. His work has the potential to influence the future of energy storage technologies significantly, reinforcing his suitability for this prestigious recognition
šEducation:
Dr. Mawuse Amedzo-Adore holds a Ph.D. in Energy and Materials Engineering from Dongguk University, Seoul, South Korea, completed in August 2023. His doctoral research, supported by the SRD Fellowship, focused on the modification of Vanadyl Phosphate (VOPOā) through intercalation reactions to develop electrode materials for metal-ion batteries and supercapacitor applications. Additionally, he conducted research projects on the synthesis and characterization of nanomaterials for lithium- and sodium-ion batteries, as well as supercapacitors. He also earned a Bachelor of Science in Chemistry from Kwame Nkrumah University of Science and Technology in Kumasi, Ghana, in June 2010, where his dissertation explored the production of bioethanol from cassava using both acid and enzyme hydrolysis methods.
š¢Work Experience:
Dr. Mawuse Amedzo-Adore is currently a Postdoctoral Research Fellow at the Flexible Display and Printed Electronic Laboratory within the Department of Chemical and Biochemical Engineering at Dongguk University, Seoul, South Korea, where he has been since September 2023. In this role, he is responsible for the research and development of materials for energy storage systems, managing laboratory operations, and supervising graduate student research while also editing manuscripts. Additionally, he serves as a Peer Journal Reviewer for the Journal of Power Sources since October 2023. Previously, he was a Visiting Graduate Student Researcher at the Energy Storage and Conversion Materials Laboratory at Korea University, Seoul, from September 2019 to July 2021, where he focused on the research and development of materials for energy storage systems and managed laboratory equipment, including an electrospinning machine, glovebox, and microwave-assisted hydrothermal machine.
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Awards:
Dr. Mawuse Amedzo-Adore was awarded the SRD Fellowship during his Ph.D. studies at Dongguk University, recognizing his exceptional research contributions and commitment to advancing the field of Energy and Materials Engineering. This fellowship supported his work on the modification of Vanadyl Phosphate (VOPOā) as electrode materials for metal-ion batteries and supercapacitor applications.
š¬Research Focus:
Dr. Mawuse Amedzo-Adore’s research focuses on the design and synthesis of nanomaterials, specifically aimed at developing advanced materials for energy conversion and storage systems. He primarily investigates energy storage systems, including lithium-ion and sodium-ion batteries, as well as supercapacitors. His work also encompasses electrode fabrication and testing, where he fabricates electrodes for energy storage applications and conducts electrochemical tests to evaluate their performance.
Publication Top Notes:
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Surfactant-Assisted NiCo2S4 for Redox Supercapacitors
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Surfactant-Assisted Binder-Free NiCo2S4 with Enhanced Electrochemical Performance in Aqueous Supercapacitor Application
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Synergistic effect of MnS@Bi2S3 nanosheets for enhanced electrochemical performance in aqueous electrolyte supercapacitor application
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All layered iron vanadate (FeV3O9.2.1H2O) as electrode for symmetric supercapacitor application in aqueous electrolyte
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Bioinspired redox-coupled conversion reaction in FeOOH-acetate hybrid nanoplatelets for Na ion battery