Post Combustion Capture (PCC) stands as a critical technological innovation within the realm of fossil fuel power plants, especially those reliant on coal or natural gas. In a concerted effort to combat climate change, PCC strategically intervenes after the combustion phase, targeting the reduction of greenhouse gas emissions, notably carbon dioxide (CO2). The process unfolds as the flue gas, a by-product of combustion enriched with CO2 and other pollutants, undergoes meticulous separation. Employing diverse technologies like chemical solvents, adsorption materials, or membranes, the aim is to capture and isolate CO2 effectively. The captured CO2, once concentrated, opens avenues for environmentally conscious management. It can be either safely transported and stored or repurposed in various industrial applications, thereby averting its release into the atmosphere. By adopting PCC, power plants can substantially curtail their carbon footprint, playing a pivotal role in ameliorating the adverse effects of fossil fuel combustion on climate change. Nevertheless, the successful implementation of PCC demands a comprehensive evaluation of its energy and cost implications. These factors are integral in determining the feasibility and potential widespread adoption of this technology in the broader landscape of power generation.
Thomas J Webster
Hebei University of Technology, United States
Hossein Hosseinkhani
Innovation Center for Advanced Technology, Matrix, Inc., United States
Hai Feng Ji
Drexel University, United States
Paulo Cesar De Morais
Catholic University of Brasilia, Brazil
Azzedine Bensalem
Long Island University, United States
Robert Buenker
Wuppertal University, Germany
Rafal Kozubski
Jagiellonian University in Krakow, Poland
Sylwia Wcislik
Kielce University of Technology, Poland
Raman Singh
Monash University-Clayton Campus, Australia
Michael I Tribelsky
Moscow State University, Russian FederationSubmit your abstract Today
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