CO2 Conversion and Utilization
Photocatalytic and Electrochemical Methods and Applications
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CO2 Conversion and Utilization
Photocatalytic and Electrochemical Methods and Applications
About This Book
CO 2 Conversion and Utilization
Comprehensive overview of current development of various catalysts in CO 2 conversion and utilization through photocatalytic and electrochemical methods
CO 2 Conversion and Utilization systematically summarizes the development of CO 2 photo- and electro-conversion and utilization, especially the reaction mechanism, engineering and technology of testing, and preparation methods and physicochemical properties of various catalytic materials. The rational design and preparation of catalysts, development of characterization technologies, and in-depth understanding of catalytic mechanisms are systematically discussed.
In particular, the various parameters influencing the photocatalytic and electrochemical CO 2 reduction are emphasized. The underlying challenges and perspectives for the future development of efficient catalysts for CO 2 reduction to specific chemicals and fuels are discussed at the end of the text.
Written by a highly qualified author with significant experience in the field, CO 2 Conversion and Utilization includes information on:
- Measurement systems and parameters for CO 2 photo/electro-conversion, CO 2 photo/electro-conversion mechanism, and Cu-based and Cu-free metal materials for electrocatalytic CO 2 reduction
- Organic-inorganic, metal organic framework, and covalent organic framework hybrid materials for CO 2 photo/electro-conversion
- Single/dual-atom catalysts, homogeneous catalysts, and high-entropy alloys for CO 2 photo/electro-conversion
- Semiconductor composite and carbon-based materials for photocatalytic CO 2 reduction, novel routes for CO 2 utilization via metal-CO 2 batteries, and CO 2 conversion into long-chain compounds
Providing comprehensive coverage of the subject, CO 2 Conversion and Utilization is of high interest for scientific researchers as well as engineers and technicians in industry, including but not limited to photochemists, electrochemists, environmental chemists, catalytic chemists, chemists in industry, and inorganic chemists.
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Table of contents
- Cover
- Table of Contents
- Title Page
- Copyright
- Preface
- 1 Measurement Systems and Parameters for CO2 Photo/ElectroâConversion
- 2 CO2 Photo/ElectroâConversion Mechanism
- 3 CuâBased Metal Materials for Electrocatalytic CO2 Reduction
- 4 CuâFree Metal Materials for Electrocatalytic CO2 Conversion
- 5 Organic-Inorganic Hybrid Materials for CO2 Photo/ElectroâConversion
- 6 Metal-Organic Framework Materials for CO2 Photoâ/ElectroâConversion
- 7 Covalent Organic Frameworks for CO2 Photo/ElectroâConversion
- 8 Single/DualâAtom Catalysts for CO2 Photo/ElectroâConversion
- 9 Homogeneous Catalytic CO2 Photo/ElectroâConversion
- 10 HighâEntropy Alloys for CO2 Photo/ElectroâConversion
- 11 Semiconductor Composite Materials for Photocatalytic CO2 Reduction
- 12 CarbonâBased Materials for CO2 Photo/ElectroâConversion
- 13 Metal-CO2 Batteries: Novel Routes for CO2 Utilization
- 14 CO2 Conversion into LongâChain Compounds
- 15 Conclusions and Perspectives
- Index
- End User License Agreement