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Informationen zum Autor Fangming Jin is a Distinguished Professor in School of Environmental Science & Engineering at Shanghai Jiao Tong University, China. She earned her PhD from Tohoku University, Japan. From 2007 to 2010, she was promoted to Professor at Tongji University, China and also an Endowed Professor sponsored by Chang Jiang Scholar Program (administered by Ministry of Education of the People’s Republic of China). In 2010, she moved to Tohoku University as a professor, and then in July 2011, she moved to Shanghai Jiao Tong University, and received an honor of "Recruitment Program of Global Experts" Talents in Shanghai. Her research focuses on the application of hydrothermal reactions for the conversion of CO2 and biomass into fuels and chemicals, to explore a potentially useful technology for improvement of the carbon cycle by mimicking nature. She has authored more than 200 scientific publications, including peer-reviewed papers, patents and book chapters, and gave about 30 plenary/keynote/invited presentations. Prof. Jin is also a Visiting Professor at Tohoku University and a Fellow of the Graduate School of Environmental Studies at Tohoku University. Zusammenfassung The book covers advances in hydrothermal reduction of CO2 into low-carbon fuels. It offers perspectives from chemical engineering, environmental chemicals, organic chemistry, inorganic chemistry, physical chemistry, geology and materials science. It addresses fundamentals and applications, associated materials, and technologies. Inhaltsverzeichnis Water under High Temperature and Pressure Conditions (and Some Special Reactions under Hydrothermal Conditions). Catalytic Hydrothermal Reactions for Small Molecules Activation. Hydrothermal Water Splitting for Hydrogen Production with Other Metals. Hydrothermal Water Splitting for Hydrogen Production with Iron. Hydrothermal CO2 Reduction with Iron to Produce Formic Acid. Hydrothermal Reduction of Carbon Dioxide to Low-Carbon Fuels. Hydrothermal CO2 Reduction with Zinc to Produce Formic Acid. Auto-Catalytic Hydrothermal CO2 Reduction with Manganese to Produce Formic Acid. Auto-Catalytic Hydrothermal CO2 Reduction with Aluminum to Produce Formic Acid. Cu-Catalyzed Hydrothermal CO2 Reduction with Zinc to Produce Methanol. Hydrothermal Reduction of CO2 with Glycerin. Hydrothermal Reduction of CO2 with Compounds Containing Nitrogen. Perspectives and Challenges of CO2 Hydrothermal Reduction ...
