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Book
ISBN: 0128162511 0128154896 9780128162514 9780128154892 Year: 2019 Publisher: Oxford, United Kingdom ; Cambridge, MA : Butterworth-Heinemann, An imprint of Elsevier,
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Geophysics --- Fluid models. --- Fluid models in geophysics --- Rotating dishpan
Book
ISBN: 1838807446 1838807438 1838807454 Year: 2019 Publisher: IntechOpen
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Swirl flows are used in a wide range of industrial applications. In non-reacting cases, examples of applications include vortex amplifiers and reactors, heat exchangers, jet pumps, and cyclone separators. In reacting cases, swirlers are widely used in combustion systems, such as gas turbines, industrial furnaces, boilers, gasoline and diesel engines, and many other practical heating devices. Effects of using swirl on flow and combustion are significant and varied, and concern, for example, aerodynamics, mixing, flame stability, intensity of combustion, and pollutant emissions. The purpose of this book is to present recent research efforts to understand and characterize swirling flows of different types and in different applications. These include gaseous, liquid, and solid fuels in order to enhance combustion systems and their energy efficiency. Swirl flows are very complex and the studies proposed in this project are based on different means, including theoretical calculations, numerical modeling, and experimental measurements.
Rotational motion. --- Gyrodynamics --- Revolving systems --- Rotating systems --- Spin (Dynamics) --- Dynamics --- Motion --- Physical Sciences --- Engineering and Technology --- Fluid Dynamics --- Fluid Mechanics --- Physics
Book
ISBN: 3039211293 3039211285 Year: 2019 Publisher: MDPI - Multidisciplinary Digital Publishing Institute
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The Tsinghua University–University of Waterloo Joint Research Center for Micro/Nano Energy & Environment Technology (JCMEET) is a platform. It was established on Nov.11, 2017. The Chairperson of University Council of Tsinghua University, Dr. Xu Chen, and the President of the University of Waterloo, Dr. Feridun Hamdullahpur, attended the opening ceremony and unveiled the nameplate for the joint research center on 29th of March, 2018. The research center serves as a platform for researchers at both universities to conduct joint research in the targeted areas, and to meet regularly for information exchange, talent exchange, and knowledge mobilization, especially in the fields of micro/nano, energy, and environmental technologies. The center focuses on three main interests: micro/nano energy technology, micro/nano pollution control technology, and relevant fundamental research. In order to celebrate the first anniversary of the Joint Research Center, we were invited to serve as the Guest Editors of this Special Issue of Materials focusing on the topic of micro/nano-materials for clean energy and environment. It collects research papers from a broad range of topics related to micro/nanostructured materials aimed at future energy resources, low emission energy conversion, energy storage, energy efficiency improvement, air emission control, air monitoring, air cleaning, and many other related applications. This Special Issue provides an opportunity and example for the international community to discuss how to actively address the energy and environment issues that we are facing.
particle size --- nanoplates --- filter paper --- potassium-based adsorbent --- Limestone --- engine filtration --- particle deposition --- airborne nanoparticle --- CaO --- air filtration --- DFT --- nanoparticles --- model --- multiscale model --- building materials --- shale --- adsorption --- passive building systems --- thermal energy storage (TES) --- As2O3 --- nanofibers --- product island --- TGA --- water quality --- oxidation kinetics --- failure --- loading performance --- kinetics --- pressure decay method --- concrete --- airborne dust --- mortar --- flame synthesis --- permeability measurement --- flame stabilizing on a rotating surface (FSRS) --- particle concentration --- submicro-fiber --- rotational speed --- phase change material (PCM) --- PM2.5 --- load modification --- oxygen carrier --- amalgam --- CO2 adsorption --- Karlovitz number --- cellulose nanofiber --- Lyocell fiber --- microscopic characteristics --- sulfation --- spectral blue shift
Book
Year: 2019 Publisher: MDPI - Multidisciplinary Digital Publishing Institute
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Plasma catalysis is gaining increasing interest for various gas conversion applications, such as CO2 conversion into value-added chemicals and fuels, N2 fixation for the synthesis of NH3 or NOx, methane conversion into higher hydrocarbons or oxygenates. It is also widely used for air pollution control (e.g., VOC
in plasma-catalysis --- gas composition --- radiofrequency plasma --- calcium carbonate decomposition --- phenanthrene --- methane reforming --- dry reforming of methane --- NH3 decomposition --- dielectric barrier discharge --- gas temperature --- relative humidity --- CO selectivity --- isotope labelling --- nanocatalyst --- packed-bed dielectric barrier discharge --- Ga–In alloys --- mineralization --- rotating gliding arc plasma --- dielectric barrier discharge (DBD) --- catalyst --- plasmas-catalysis --- H2S oxidation --- post plasma-catalysis --- naphthalene --- VOC abatement --- nonstoichiometry --- zeolites --- H2 generation --- tar destruction --- adsorption-plasma catalysis --- NOx conversion --- catalyst preparation --- CeO2 --- nonequilibrium plasma --- non-thermal plasmas --- mode transition --- bimetal --- DBD plasma --- surface filament --- self-cooling --- indium --- plasma catalysis --- gallium --- perovskite catalysts --- ammonia synthesis --- packing materials --- air pollution --- toluene --- particle-in- cell/Monte Carlo collision method --- CO2 decomposition --- Manganese
Book
Year: 2019 Publisher: MDPI - Multidisciplinary Digital Publishing Institute
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Plasma catalysis is gaining increasing interest for various gas conversion applications, such as CO2 conversion into value-added chemicals and fuels, N2 fixation for the synthesis of NH3 or NOx, methane conversion into higher hydrocarbons or oxygenates. It is also widely used for air pollution control (e.g., VOC
in plasma-catalysis --- gas composition --- radiofrequency plasma --- calcium carbonate decomposition --- phenanthrene --- methane reforming --- dry reforming of methane --- NH3 decomposition --- dielectric barrier discharge --- gas temperature --- relative humidity --- CO selectivity --- isotope labelling --- nanocatalyst --- packed-bed dielectric barrier discharge --- Ga–In alloys --- mineralization --- rotating gliding arc plasma --- dielectric barrier discharge (DBD) --- catalyst --- plasmas-catalysis --- H2S oxidation --- post plasma-catalysis --- naphthalene --- VOC abatement --- nonstoichiometry --- zeolites --- H2 generation --- tar destruction --- adsorption-plasma catalysis --- NOx conversion --- catalyst preparation --- CeO2 --- nonequilibrium plasma --- non-thermal plasmas --- mode transition --- bimetal --- DBD plasma --- surface filament --- self-cooling --- indium --- plasma catalysis --- gallium --- perovskite catalysts --- ammonia synthesis --- packing materials --- air pollution --- toluene --- particle-in- cell/Monte Carlo collision method --- CO2 decomposition --- Manganese
Book
Year: 2019 Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Abstract | Keywords | Export | Availability | Bookmark
Loading...Choose an application
- Reference Manager
- EndNote
- RefWorks (Direct export to RefWorks)
Plasma catalysis is gaining increasing interest for various gas conversion applications, such as CO2 conversion into value-added chemicals and fuels, N2 fixation for the synthesis of NH3 or NOx, methane conversion into higher hydrocarbons or oxygenates. It is also widely used for air pollution control (e.g., VOC
in plasma-catalysis --- gas composition --- radiofrequency plasma --- calcium carbonate decomposition --- phenanthrene --- methane reforming --- dry reforming of methane --- NH3 decomposition --- dielectric barrier discharge --- gas temperature --- relative humidity --- CO selectivity --- isotope labelling --- nanocatalyst --- packed-bed dielectric barrier discharge --- Ga–In alloys --- mineralization --- rotating gliding arc plasma --- dielectric barrier discharge (DBD) --- catalyst --- plasmas-catalysis --- H2S oxidation --- post plasma-catalysis --- naphthalene --- VOC abatement --- nonstoichiometry --- zeolites --- H2 generation --- tar destruction --- adsorption-plasma catalysis --- NOx conversion --- catalyst preparation --- CeO2 --- nonequilibrium plasma --- non-thermal plasmas --- mode transition --- bimetal --- DBD plasma --- surface filament --- self-cooling --- indium --- plasma catalysis --- gallium --- perovskite catalysts --- ammonia synthesis --- packing materials --- air pollution --- toluene --- particle-in- cell/Monte Carlo collision method --- CO2 decomposition --- Manganese
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