Energy Materials Discovery: Enabling a Sustainable FutureDocumenting, through the eyes of a practicing materials chemist, an epic journey to make the energy transition from non-renewable to renewable forms possible, this unique book will crosscut the disciplines of chemistry, physics, materials science and engineering. It is mainly about a bottom-up synthetic chemistry approach to energy materials rather than a top-down engineering physics methodology. A distinctive feature of the book is the inclusion of the use of artificial intelligence, machine learning and robotic materials discovery. Helping many students and researchers, funding agencies and industries, media and investors to understand the story of energy materials, the book will be a unique addition to the literature. |
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Energy Materials Discovery: Enabling a Sustainable Future Geoffrey A Ozin,Joel Y Y Loh Limited preview - 2022 |
Energy Materials Discovery: Enabling a Sustainable Future Geoffrey A. Ozin,Joel Y. Y. Loh Limited preview - 2022 |
Common terms and phrases
absorption achieve active anode applications approach associated band battery capacity carbon catalyst cell challenges charge Chem chemical chemistry compared composition computational concentration conductivity conversion Copyright cost crystal cycle density depend device diffusion direct effect efficiency electricity electrolyte electronic elements emerging emissions enable energy materials engineering example exist field Figure fuel fuel cell function future heat human hydrogen illustrated increase industrial layer learning light machine materials materials discovery mechanical metal methods nanomaterials nanoscale Nature operating optical optimization organic oxide oxygen performance permission perovskite phase photocatalyst physical possible potential practice production properties provides range reaction redox reduce renewable Reproduced from ref respectively scale separation shown in Figure shows solar solid solid-state stability storage structure surface sustainable synthesis temperature thermal transport Wang