Details
Recent Developments in Functional Materials for Artificial Photosynthesis
ISSN 1. Aufl.
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CHF 230.00 |
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| Verlag: | Royal Society Of Chemistry |
| Format: | EPUB |
| Veröffentl.: | 08.03.2023 |
| ISBN/EAN: | 9781839167775 |
| Sprache: | englisch |
| Anzahl Seiten: | 368 |
DRM-geschütztes eBook, Sie benötigen z.B. Adobe Digital Editions und eine Adobe ID zum Lesen.
Beschreibungen
Artificial photosynthesis is the process of converting solar energy into useful fuels and represents a significant achievement in the production of clean energy for the planet. In the process, energy is generated from water and CO
<sub>2</sub> reduction using solar-powered photocatalysis. This book provides a comprehensive overview of recently developed, multifunctional materials as visible light-driven catalysts, their mechanisms and applications in solar energy utilisation and conversion. Chapters highlight the use of different approaches such as molecular catalysis, nanomaterials systems, as well as thin-films for solar-driven evolution of renewable fuels, such as hydrogen. This is the first book to give an overview of this area, with chapters specifically interesting for those looking towards industrial applications. With in-depth discussions ranging from understanding, to engineering of materials and applied devices, it will be suitable for industry professionals, researchers and students interested in understanding of the current state of photocatalysis research and its possible applications in the energy domain.
<sub>2</sub> reduction using solar-powered photocatalysis. This book provides a comprehensive overview of recently developed, multifunctional materials as visible light-driven catalysts, their mechanisms and applications in solar energy utilisation and conversion. Chapters highlight the use of different approaches such as molecular catalysis, nanomaterials systems, as well as thin-films for solar-driven evolution of renewable fuels, such as hydrogen. This is the first book to give an overview of this area, with chapters specifically interesting for those looking towards industrial applications. With in-depth discussions ranging from understanding, to engineering of materials and applied devices, it will be suitable for industry professionals, researchers and students interested in understanding of the current state of photocatalysis research and its possible applications in the energy domain.
This book will give a comprehensive overview of recently developed, multifunctional materials as visible light-driven catalysts, their mechanisms and applications in solar energy utilization and conversion.
Multidisciplinary Approaches to Solar-driven Water Splitting and Carbon Dioxide Conversion;SrTiO
<sub>3</sub>-based Perovskite Photocatalysts for Efficient Solar-driven Overall Water Splitting and CO
<sub>2</sub> Reduction;Recent Developments in (Oxy)nitride Photocatalysts With Narrow Bandgaps for Solar-driven Water Splitting;Recent Advances in (Oxy)sulfide Photocatalysts for Solar-driven Water Splitting and CO
<sub>2</sub> Reduction;Efficacy of Bismuth Oxyhalides (BiOX-based) Materials for Enhanced Photocatalysis;Molecular Catalysts Immobilised on Photocathodes for Solar Fuel Generation;Recent Advances in the Development of Metal–Organic Frameworks-based Photocatalysts for Water Splitting and CO
<sub>2</sub> Reduction;2D Nanomaterials-based Heterostructures for H
<sub>2</sub>O Splitting and CO
<sub>2</sub> Reduction;Role of Co-catalysts for Photocatalytic H
<sub>2</sub>O Splitting and CO
<sub>2</sub> Reduction;Semiconductor Quantum Dots for Water Splitting and CO
<sub>2</sub> Photoreduction;Computational Approaches to Materials Design for Enhanced Photocatalytic Activity;Scaling Up Photocatalysts and New Devices for Solar Water Splitting and CO
<sub>2</sub> Reduction
<sub>3</sub>-based Perovskite Photocatalysts for Efficient Solar-driven Overall Water Splitting and CO
<sub>2</sub> Reduction;Recent Developments in (Oxy)nitride Photocatalysts With Narrow Bandgaps for Solar-driven Water Splitting;Recent Advances in (Oxy)sulfide Photocatalysts for Solar-driven Water Splitting and CO
<sub>2</sub> Reduction;Efficacy of Bismuth Oxyhalides (BiOX-based) Materials for Enhanced Photocatalysis;Molecular Catalysts Immobilised on Photocathodes for Solar Fuel Generation;Recent Advances in the Development of Metal–Organic Frameworks-based Photocatalysts for Water Splitting and CO
<sub>2</sub> Reduction;2D Nanomaterials-based Heterostructures for H
<sub>2</sub>O Splitting and CO
<sub>2</sub> Reduction;Role of Co-catalysts for Photocatalytic H
<sub>2</sub>O Splitting and CO
<sub>2</sub> Reduction;Semiconductor Quantum Dots for Water Splitting and CO
<sub>2</sub> Photoreduction;Computational Approaches to Materials Design for Enhanced Photocatalytic Activity;Scaling Up Photocatalysts and New Devices for Solar Water Splitting and CO
<sub>2</sub> Reduction
<p>Dr. Srabanti Ghosh presently working as Senior Scientist, Energy Materials & Devices Division, in CSIR - Central Glass and Ceramic Research Institute, Kolkata, India. She received her PhD degree in Chemistry from UGC-DAE Consortium for Scientific Research, Kolkata Centre, and Jadavpur University, India and completed postdoctoral programs at the University of Paris SUD, France (Marie Curie Cofund). She worked as GOT ENERGY TALENT Cofund Marie Curie Fellow Researcher in UNIVERSIDAD DE ALCALA, Spain. Her main research interests include synthesis, characterization of functional materials at nanoscale and their photoelectrochemical properties for energy conversion devices, photocatalysts, electrocatalysts, fuel cells and biosensors applications.  She co-authored 80 publications in international scientific journals, 2 patent, edited 4 books and contributed 19 book chapters covering the large fields of photocatalysis, conjugated polymer, heterostructure nanomaterials, and water treatment. She routinely acts as a reviewer of SCI Journals from different editorials (RSC, ACS, ELSEVIER, Wiley, Springer Nature, MDPI, among others). Her current research work is focused on nanohybrid materials, conducting polymer nanostructures for solar light harvesting, photocatalysis applications.</p>
<p>Qian Wang is currently an Associate Professor at Nagoya University, Japan. She obtained her Ph.D. in 2014 at the University of Tokyo, Japan, where she worked on the development of perovskite-type oxide photocatalysts for visible-light-driven water splitting. She then worked as a postdoctoral researcher at the Japan Technological Research Association of Artificial Photosynthetic Chemical Processes (ARPChem) on the development of standalone photocatalyst devices for overall water splitting. In 2018, she became a Marie Sklodowska-Curie Research Fellow at the University of Cambridge to develop inorganic-organic hybrid photocatalysts. She joined Nagoya University as an Associate Professor in May 2021 and established her research group, which is currently developing new materials, approaches, and technologies for solar energy storage in the form of renewable fuels via artificial photosynthesis.</p>
<p>Qian Wang is currently an Associate Professor at Nagoya University, Japan. She obtained her Ph.D. in 2014 at the University of Tokyo, Japan, where she worked on the development of perovskite-type oxide photocatalysts for visible-light-driven water splitting. She then worked as a postdoctoral researcher at the Japan Technological Research Association of Artificial Photosynthetic Chemical Processes (ARPChem) on the development of standalone photocatalyst devices for overall water splitting. In 2018, she became a Marie Sklodowska-Curie Research Fellow at the University of Cambridge to develop inorganic-organic hybrid photocatalysts. She joined Nagoya University as an Associate Professor in May 2021 and established her research group, which is currently developing new materials, approaches, and technologies for solar energy storage in the form of renewable fuels via artificial photosynthesis.</p>
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