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Nanomaterials for CO2 Capture, Storage, Conversion and Utilization

Forfatter: info mangler
Bog
  • Format
  • Bog, paperback
  • Engelsk

Beskrivelse

The gradual increase of population and the consequential rise in the energy demands in recent years have led to the widespread use of fossil fuels. CO2 transformation by various processes is considered as a promising alternative technology. This book sets out the fundaments of how nanomaterials are being used for this purpose. Nanomaterials for CO2 Capture, Storage, Conversion and Utilization summarizes the research, development and innovations in the capture, storage, transformation and utilization of CO2 into useful products and raw chemicals for industry. This is achieved by using advanced processes such as CO2 reforming, bi-reforming and tri-reforming of hydrocarbons or biomass derivatives; homogeneous and heterogeneous hydrogenation; photochemical reduction; photoelectrochemical reduction; electrochemical reduction; biochemical reduction; supercritical CO2 technology; advanced catalyst synthesis for CO2 conversion; organic carbonates for polymers synthesis from CO2, and CO2 capture and sequestration. The systematic and updated reviews on the mentioned sectors, especially on the use of nanotechnology for the transformation of CO2 is scarce in the literature. Thus, the book addresses the recent knowledge gaps and potential solutions of the storage, utilization and transformation of CO2 as well as its promising applications. This is an important reference source for materials scientists, engineers and energy scientists who want to understand how nanotechnology is helping us to solve some of the world’s major energy problems.

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  • Vægt790 g
  • coffee cup img
    10 cm
    book img
    19,1 cm
    23,5 cm

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    Technology Environmental Global-warming Electronic structure. Environment Fossil Nanoparticles. Nanotubes Electrocatalysis Sustainable development Porous materials Catalysts Chemicals Carbon dioxide Photocatalysis Atmosphere Energy conversion Fuel Energy Hydrocarbons Temperature Climate change mitigation Nanocomposites Plasma Industrial CO2 reduction Nanocrystalline CO2-sequestration Value-added chemicals Greenhouse Nanomaterials Photochemical Value Added Products Polymer Atmospheric Emissions Products Carbon Dioxide Utilization Carbon cycle Carbon capture and storage (CCS) CO2-Adsorption Reaction Capturing Electrochemical Heterogeneous catalysts Solar fuels Greenhouse gas CO2 photoreduction Catalytic Surface structure And nanohollow structures Artificial photosynthetic system Catalyst criteria (design) CO2 to fuel/chemical conversion carbon dioxide reduction Cyclic and liner carbonate Condensation reaction Covalent Organic Frameworks ClHmOn valuable compounds CO2 hydrogenation CO2 reduction (atomistic hydrogenation) Electrons transfer Metal Atoms Nanoporous Nanostructured (nanoparticulated/mesoporous) photocatalyst Photoelectrochemical CO2 reduction Photoreduction Redox (electrochemical) nature Product selectivity Liquid energy fuel Single-atom catalyst thermochemical Transient H-atom generation Semiconducting solar-energy materials Shaped-controlled Metal nanocatalysts Visible light responsive Reactive radical species (building blocks) Titania-based nanomaterials Standard redox potentials
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