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gsb.stanford.edu
research
https://www.gsb.stanford.edu/faculty-research/working-papers/carbon-capture-u…
# Carbon Capture and Utilization in the Industrial Sector. The fabrication and manufacturing of industrial commodities such as iron, glass and cement is carbon-intensive. A major reason capture of carbon dioxide from flue gases of industrial processes has not been widely adopted as a climate mitigation strategy is due to the lack of economic incentives for capturing CO2 on a scale that will impact climate. Yet, abatement opportunities do exist for the industrial sector, provided the scale of such processes is aligned well with CO2 utilization. This work develops a model that examines the full cost of separating, compressing and transporting CO2 of various industrial processes (sources), and pairing them with appropriate utilization opportunities (sinks). We find that – given the relatively higher concentrations of CO2 in flue gases from industrial processes – the full cost of abatement is lower than that of the power sector. We apply this methodology to a regional case study, which shows steel and cement manufacturing as having the lowest levelized cost of abatement.
E
energyinnovation.org
article
https://energyinnovation.org/expert-voice/industrial-carbon-capture-explained…
Carbon capture, utilization, and storage (CCUS) is the process of capturing carbon emissions from fossil fuel-fired power plants or industrial facilities. Carbon capture, utilization, and storage (CCUS) can help reduce emissions across the world’s most difficult-to-decarbonize industrial sectors — but its application should be limited to niche uses that cannot be readily electrified like carbon-intensive feedstocks and some high-temperature heat needs. CCUS is the process of capturing carbon emissions from fossil fuel-fired power plants or industrial facilities. Among CCUS’s most promising long-term applications in the industrial sector is the potential to reduce “process emissions,” or emissions separate from energy use that occur as a byproduct of turning raw materials into the end product. But CCUS could play an essential role in reducing near-term emissions throughout high-temperature industrial processes alongside low-carbon fuels. CCUS is a promising method of reducing long-term emissions from some of the hardest to clean up industrial processes and could also be effective in reducing near-term emissions from sectors where decarbonization technology is not yet commercially viable, or when solutions remain otherwise cost-prohibitive.
D
drawdown.org
article
https://drawdown.org/sector-2025/industrial-carbon-removal
Direct air capture (DAC) is an industrial process that captures CO₂ from the air and then injects it deep underground for permanent, geologic storage.
N
netl.doe.gov
official
https://www.netl.doe.gov/carbon-capture/industrial
Point source carbon capture from industrial sources (e.g., chemical production [ammonia, hydrogen, petrochemical], mineral production [cement and lime], natural gas processing, and iron and steel production plants) separates carbon dioxide (CO2) emissions from the plant’s flue gas or other exhaust stream that would otherwise have been released to the atmosphere. Industrial sources that have a highly concentrated stream of CO2, such as natural gas processing, fertilizer production, hydrogen production, and ethanol production, have lower energy requirements for CO2 separation. For lower-concentration industrial sources, such as iron and steel production, cement manufacturing, and petroleum refining facilities, significant challenges exist in developing carbon capture technologies, including energy requirements, differing gas compositions, varying process temperatures and pressures, and various contaminants. [iii] “Air Products and Chemicals, Inc.: Demonstration of CO2 Capture and Sequestration of Steam Methane Reforming Process Gas Used for Large-Scale Hydrogen Production.” National Energy Technology Laboratory.
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
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cleanplanetchemical.com
article
https://www.cleanplanetchemical.com/top-11-ways-to-reduce-the-carbon-footprin…
There are numerous ways to help reduce industrial carbon emissions: adopting new green technologies like solvent recovery, employing waste reduction strategies, or empowering employees to make green choices, to name a few. **Upgrading equipment, optimizing processes, and implementing energy-saving technologies** can substantially reduce energy consumption and, consequently, industrial carbon emissions. Encourage your suppliers to adopt eco-friendly practices, source sustainable materials, and reduce their own industrial carbon emissions. As a result, businesses not only save costs by reducing their dependence on expensive virgin solvents but also contribute to a more sustainable environment by mitigating GHGs. CleanPlanet’s AlwaysClean solvent recyclers come accompanied with the MyCleanPlanet portal—a real-time monitoring platform that provides data on solvent recovery yield, waste production, energy consumption, GHG emissions reduction, and more. By integrating these strategies, you can significantly reduce your industrial carbon emissions footprint and contribute to a more sustainable industrial landscape. ⁹Massachusetts Institute of Technology (2021) – Reducing Industrial Carbon Emissions. ¹⁰Massachusetts Institute of Technology (2021) – Reducing Industrial Carbon Emissions.
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
cas.org
article
https://www.cas.org/resources/cas-insights/carbon-capture-technology
[English](https://www.cas.org/resources/cas-insights/carbon-capture-technology). [Portuguese](https://www.cas.org/pt-br/resources/cas-insights/carbon-capture-technology). [Korean](https://www.cas.org/ko/resources/cas-insights/carbon-capture-technology). [Spanish](https://www.cas.org/es-es/resources/cas-insights/carbon-capture-technology). [Chinese](https://www.cas.org/zh-hans/resources/cas-insights/carbon-capture-technology). [Japanese](https://www.cas.org/ja/resources/cas-insights/carbon-capture-technology). [English](https://www.cas.org/resources/cas-insights/carbon-capture-technology). [Portuguese](https://www.cas.org/pt-br/resources/cas-insights/carbon-capture-technology). [Korean](https://www.cas.org/ko/resources/cas-insights/carbon-capture-technology). [Spanish](https://www.cas.org/es-es/resources/cas-insights/carbon-capture-technology). [Chinese](https://www.cas.org/zh-hans/resources/cas-insights/carbon-capture-technology). [Japanese](https://www.cas.org/ja/resources/cas-insights/carbon-capture-technology). [Emerging Science](https://www.cas.org/resources/topic/emerging-science)[Sustainability](https://www.cas.org/resources/topic/sustainability)[](https://www.cas.org/resources/cas-insights/carbon-capture-technology#)[](https://www.cas.org/resources/cas-insights/carbon-capture-technology#). [](https://www.cas.org/resources/cas-insights/carbon-capture-technology#)[](https://www.cas.org/resources/cas-insights/carbon-capture-technology#)[](https://www.cas.org/resources/cas-insights/carbon-capture-technology#)[](https://www.cas.org/resources/cas-insights/carbon-capture-technology#). [](https://www.cas.org/resources/cas-insights/carbon-capture-technology#). [ CAS Lead Scientist, Materials](https://www.cas.org/resources/cas-insights/carbon-capture-technology#). [Latest publication trends in carbon capture](https://www.cas.org/resources/cas-insights/carbon-capture-technology#latest-publication-trends-in-carbon-capture). [New drivers of carbon capture commercialization](https://www.cas.org/resources/cas-insights/carbon-capture-technology#new-drivers-of-carbon-capture-commercialization). [Patent concepts showing the highest growth](https://www.cas.org/resources/cas-insights/carbon-capture-technology#patent-concepts-showing-the-highest-growth). [Real-world applications of carbon capture technology](https://www.cas.org/resources/cas-insights/carbon-capture-technology#real-world-applications-of-carbon-capture-technology). [Next steps for carbon capture technology](https://www.cas.org/resources/cas-insights/carbon-capture-technology#next-steps-for-carbon-capture-technology). Carbon capture technologies are an important component of global emissions mitigation, and as we found in a recent analysis of the [CAS Content Collection TM](https://www.cas.org/cas-data), the largest human-curated repository of scientific information, they’re now closer to widespread commercialization. Carbon capture methods have existed for decades, and as we explored in an earlier [CAS Insights article](https://www.cas.org/resources/cas-insights/carbon-capture-sequestration), there are numerous approaches to capturing carbon, including biological, chemical, and geological methods. We mapped carbon capture-related publications using CAS indexing data that assigns publications to [sections](https://www.cas.org/training/documentation/references/ca-sections) based on their content area. For industrial processes with high CO 2 concentrations, such as ethanol production or natural gas processing, the cost can [range](https://www.iea.org/commentaries/is-carbon-capture-too-expensive) from $15-$25 per ton of CO 2. [](https://www.cas.org/resources/cas-insights/carbon-capture-technology#)[Subscribe to CAS Insights](https://www.cas.org/cas-insights-subscribe).