Gas Capture Processes
Zhang, Zhien
Gas Capture Processes - Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute 2020 - 1 electronic resource (440 p.)
Open Access
This book introduces the recent technologies introduced for gases capture including CO2, CO, SO2, H2S, NOx, and H2. Various processes and theories for gas capture and removal are presented. The book provides a useful source of information for engineers and specialists, as well as for undergraduate and postgraduate students in the fields of environmental and chemical science and engineering.
Creative Commons
English
books978-3-03928-781-9 9783039287802 9783039287819
10.3390/books978-3-03928-781-9 doi
History of engineering & technology
in situ gasification chemical looping combustion high-flux circulating fluidized bed counter-flow moving bed gas leakage coupling mechanism carbon capture and utilization biogas upgrading calcium carbonate precipitation chemical absorption gas pressure gas content gas basic parameters rapid estimation technology supercritical water oxidation high-pressure separation oxygen recovery energy recovery economic analysis coal-direct chemical looping combustion theoretical methodology high-flux pressure gradient gas mole fraction activity UNIFAC phase equilibrium threshold value CO2 capture calcium looping chemical sorption anti-attrition pore-former particle size Reaction kinetics carbon dioxide N-methyldiethanolamine L-Arginine stopped flow technique carbon capture CO2 sequestration steel-making waste steel slag H2S absorption amine solutions glycols desulfurization aqueous and non-aqueous solutions gas diffusion unipore diffusion model bidisperse diffusion model dispersive diffusion model refinery plants industrial gas streams petrochemical processes waste gases activated carbons catalytic activation physicochemical structure SO2 adsorption optimal conceptual design market prediction economic uncertainty environmental impact carbon dioxide separation Aspen Plus CCGT Taguchi Minitab optimization 2-Amino-2-Methyl-1-Propanol modelling and Simulation post-combustion capture exergy analysis flowsheeting configurations nanofluids absorption intensification mass transfer coefficient bubble column global warming membrane contactor removal of NO2 and CO2 coke oven carbonaceous deposits spectral analysis mechanism arsenene doping first principles study gas adsorption two-dimensional waste polyurethane foam physical activation high selectivity ultra-micropore mechanical activation iron ore carbonation calcination recyclability mechanochemical reactions carbonation kinetics MXene gas separation Knudsen diffusion molecular sieving transport mechanism spiral nozzle gas absorption spray atomization droplet size droplet velocity gas emission capture CO2
Gas Capture Processes - Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute 2020 - 1 electronic resource (440 p.)
Open Access
This book introduces the recent technologies introduced for gases capture including CO2, CO, SO2, H2S, NOx, and H2. Various processes and theories for gas capture and removal are presented. The book provides a useful source of information for engineers and specialists, as well as for undergraduate and postgraduate students in the fields of environmental and chemical science and engineering.
Creative Commons
English
books978-3-03928-781-9 9783039287802 9783039287819
10.3390/books978-3-03928-781-9 doi
History of engineering & technology
in situ gasification chemical looping combustion high-flux circulating fluidized bed counter-flow moving bed gas leakage coupling mechanism carbon capture and utilization biogas upgrading calcium carbonate precipitation chemical absorption gas pressure gas content gas basic parameters rapid estimation technology supercritical water oxidation high-pressure separation oxygen recovery energy recovery economic analysis coal-direct chemical looping combustion theoretical methodology high-flux pressure gradient gas mole fraction activity UNIFAC phase equilibrium threshold value CO2 capture calcium looping chemical sorption anti-attrition pore-former particle size Reaction kinetics carbon dioxide N-methyldiethanolamine L-Arginine stopped flow technique carbon capture CO2 sequestration steel-making waste steel slag H2S absorption amine solutions glycols desulfurization aqueous and non-aqueous solutions gas diffusion unipore diffusion model bidisperse diffusion model dispersive diffusion model refinery plants industrial gas streams petrochemical processes waste gases activated carbons catalytic activation physicochemical structure SO2 adsorption optimal conceptual design market prediction economic uncertainty environmental impact carbon dioxide separation Aspen Plus CCGT Taguchi Minitab optimization 2-Amino-2-Methyl-1-Propanol modelling and Simulation post-combustion capture exergy analysis flowsheeting configurations nanofluids absorption intensification mass transfer coefficient bubble column global warming membrane contactor removal of NO2 and CO2 coke oven carbonaceous deposits spectral analysis mechanism arsenene doping first principles study gas adsorption two-dimensional waste polyurethane foam physical activation high selectivity ultra-micropore mechanical activation iron ore carbonation calcination recyclability mechanochemical reactions carbonation kinetics MXene gas separation Knudsen diffusion molecular sieving transport mechanism spiral nozzle gas absorption spray atomization droplet size droplet velocity gas emission capture CO2