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netl.doe.gov
official
https://netl.doe.gov/carbon-management/carbon-capture
The U.S. Department of Energy/National Energy Technology Laboratory’s (DOE/NETL) Point Source Carbon Capture (PSCC) Program is developing the next generation of advanced carbon dioxide (CO2) capture technologies (e.g., membrane, solvent, sorbent, chemical looping) focusing on reduced cost and improved performance and reliability. DOE’s Office of Fossil Energy and Carbon Management (FECM) has adopted a comprehensive, multipronged approach that involves the coupling of CO2 capture from a point source (fossil fuel-based power generation and industrial sources, e.g. hydrogen, petrochemical, cement production plants) with (1) CO2 transport via pipeline and injection underground for long-duration storage, (2) conversion into valuable products such as fuels, chemicals and building materials, or (3) use for enhanced hydrocarbon (oil or gas) recovery. Research and development (R&D) efforts to date have led to significant improvements in cost and performance through implementation of energy and process efficiencies and development of advanced CO2 capture media (e.g., solvents, sorbents, and membranes).
I
industrialdecarbonizationnetwork.com
article
https://www.industrialdecarbonizationnetwork.com/emissions-management/article…
# Industrial Carbon Capture: Exploring the Top Methods, Trends & Technologies. Industrial carbon capture, a crucial component of these efforts, refers to the technologies and methods designed to capture emissions from industrial processes before they reach the atmosphere. While the industrial sector explores effective options to reduce overall CO₂ emissions, the primary method to reduce emissions from large industrial sources is carbon capture and storage (CCS). In some cases, captured CO₂ can be used in other manufacturing or industrial processes instead of being stored, leading to the term carbon capture, utilization and storage (CCUS). With that in mind, recent breakthroughs in technologies could change carbon capture as we know it and help the industrial sector minimize its carbon footprint. While chemical looping technology is still experimental, it holds promise for significantly reducing carbon emissions in industries heavily dependent on fossil fuels. As a low-carbon energy source, Bioenergy with Carbon Capture and Storage can significantly contribute to decarbonizing the economy.
C
carboncapturemagazine.com
article
https://carboncapturemagazine.com/articles/methods-and-techniques-for-co2-cap…
Capturing and storing carbon dioxide in underground wells has the potential to become the most consequential technological deployment in the history of the broader biofuels industry. Deploying effective carbon capture and storage at biofuels plants will cement ethanol and biodiesel as the lowest carbon liquid fuels commercially available in the marketplace. The Sustainable Fuels Summit: SAF, Renewable Diesel, and Biodiesel is a premier forum designed for producers of biodiesel, renewable diesel, and sustainable aviation fuel (SAF) to learn about cutting-edge process technologies, innovative techniques, and equipment to optimize existing production. Taking place August 25-27, 2026 in Tacoma, Washington, the North American SAF Conference & Expo, produced by SAF Magazine, in collaboration with the Commercial Aviation Alternative Fuels Initiative (CAAFI) will showcase the latest strategies for aviation fuel decarbonization, solutions for key industry challenges, and highlight the current opportunities for airlines, corporations and fuel producers.
C
ccsknowledge.com
article
https://ccsknowledge.com/tools-resources/co2-emissions-across-industries/
Carbon capture, utilization and storage (CCUS) is one of the only proven solutions available to reduce carbon dioxide (CO2) emissions from industries such as
B
bgs.ac.uk
article
https://www.bgs.ac.uk/discovering-geology/climate-change/carbon-capture-and-s…
Different options to try to reduce overall CO2 emissions are being investigated, but the main way to reduce CO2 emissions from large industrial sources is called carbon capture and storage, or CCS. CO2 can be captured from large sources, such as power plants, natural gas processing facilities and some industrial processes. Thus even though CCS would increase the cost of electricity from a biomass power plant, customers would know that electricity produced there would actually be reducing the CO2 content of the atmosphere, making this technology particularly attractive. The concept is to capture CO2 produced by burning coal in power stations, compress it, pipe it away from the plant and then store it deep underground. Most co-firing power plants burn solid biomass like wood and agricultural waste along with coal, but some can burn a mix of natural gas and biogas. A fossil-fuel power plant is one that burns fossil fuels such as coal, natural gas or petroleum (oil) to produce electricity.
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iea.org
article
https://www.iea.org/energy-system/carbon-capture-utilisation-and-storage
* The **United States** announced important opportunities in 2023 that are expected to boost CCUS project development, including USD 1.7 billion for carbon capture demonstration projects and USD 1.2 billion for direct air capture (DAC) hubs under the 2021 Infrastructure Investment and Jobs Act. Close to ten large-scale (capture capacity over 100 000 tCO2/year, and over 1 000 tCO2/yr for DAC applications) capture facilities entered operation in 2023, including the Blue Flint ethanol project, Linde Clear Lake capture facility, and Heirloom and Global thermostat’s first 1,000 tCO2/yr facilities in the United States, and four projects in China (the Jiling Petrochemical CCUS facility, the CNOOC Enping oil field, the first phase of the Guanghui Energy CCUS integration project and the China Energy Taizhou power plant). The database covers all CCUS projects commissioned since the 1970s with an announced capacity of more than 100 000 t per year (or 1 000 t per year for direct air capture facilities) and a clear scope for reducing emissions.
C
climate.mit.edu
research
https://climate.mit.edu/explainers/carbon-capture
Carbon capture and storage is a technology that captures the carbon dioxide from burning fossil fuels before it is released to the atmosphere.
C
capturemap.no
article
https://www.capturemap.no/carbon-capture-technologies/
These terms are widely used in the industry, and we decided to adapt them for the main categories in our overview of carbon capture technologies in CaptureMap. However when we looked into the details we started running into issues linked to different definitions and criteria for categorising capture projects. Our take on it is that those capture technology categories were mostly defined at a time where power plants were the main targets for carbon capture, and therefore combustion was the main process to be considered. Next on our overview of carbon capture technologies we will talk about oxy-fuel, since it is, in our view, the category most related to post-combustion. > Pre-combustion carbon capture converts fuel into a mixture of hydrogen, CO2 and other gases, through gasification or reforming processes. As mentioned earlier, most of the capacity for carbon capture projects already in operations is concentrated within inherent process capture and pre-combustion. This indicates that the actual capture technology is likely to be inherent process capture or pre-combustion, increasing further the share of capture projects capacities within those categories.