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texassig.org
research
https://texassig.org/research/5cwoycaxxf5gntzkrmuzkafqw3kwpu
Carbon sequestration, also known as carbon capture, utilization, and storage (CCUS), describes a wide range of technologies that isolate, extract, and store carbon dioxide (CO2) emissions from energy or industrial sources in order to prevent their long-term presence in the atmosphere. Direct Air Capture is the main approach through which CCUS technology allows for carbon storage. * H.R. 1166, USE IT Act: a proposal to amend the Clean Air Act by directing the U.S. Environmental Protection Agency (EPA) to conduct carbon capture research activities, requiring the Department of Energy (DOE) to submit a report to Congress about the potential risks and benefits of CO2 storage in saline formations, and directing the Council on Environmental Quality (CEQ) to issue guidance on the development of CO2 storage projects. While these aspects of CO2 utilization and emissions reductions are not well researched or developed to scale, further advancements can be made, and these processes create strong potential for future additional use of carbon capture, utilization, and storage technology.
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jpt.spe.org
article
https://jpt.spe.org/twa/4-cutting-edge-ccs-technologies-reshaping-the-future-…
# 4 Cutting-Edge CCS Technologies Reshaping the Future of Carbon Capture. Carbon capture and storage (CCS) represents a suite of advanced technologies designed to capture carbon dioxide (CO2), a major greenhouse gas, and safely store it underground to mitigate its impact on climate change. As highlighted in the Global CCS Institute's CCS Technologies 2024 report, these innovations are reshaping industries like petroleum and energy, playing a pivotal role in the global energy transition. Central to the technology are the oxy-combustor and CO2 convective reformer, which utilize oxy-combustion and heat integration to improve thermal efficiency while eliminating the need for energy-intensive carbon capture systems **(Fig. 1)**. The DMX process, developed by IFPEN and marketed by Axens, is a second-generation carbon capture technology that uses a demixing solvent to reduce energy consumption by nearly 30% compared to traditional mono ethanol amine-based processes **(Fig. 4)**. energy transition, energy education, carbon emissions, carbon capture and storage, Baker Hughes, innovation, sustainability, engineering education.
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sciencedirect.com
article
https://www.sciencedirect.com/science/article/pii/S0016236125030017
It also critically analyzes emerging approaches such as direct air capture (DAC), chemical looping combustion (CLC), and speculative concepts
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netzeroinsights.com
article
https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbo…
[Skip to content](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/#content). * Use Cases Close Use Cases Open Use Cases  ## For Investors Move faster with conviction in emerging transition markets. * [Insights](https://netzeroinsights.com/resources/)Close Insights Open Insights  ## Reports In-depth market intelligence and data-driven analysis. [](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/#elementor-action%3Aaction%3Dpopup%3Aopen%26settings%3DeyJpZCI6IjE5NzM5IiwidG9nZ2xlIjpmYWxzZX0%3D). [Linkedin](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/)[Envelope](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/). . Investment in **[GHG capture, removal, and storage](https://stateofclimatetech.com/)** is growing, rising from 0.7% of Climate Tech funding in 2020 to 3.5% in 2024. An estimated **[$196 billion in investment](https://www.woodmac.com/news/opinion/ccus-196-billion-investment-opportunity/)** is needed over the next decade to develop global carbon capture, utilization, and storage (CCUS) infrastructure. . [**CarbonQuest**](https://carbonquest.com/) delivers modular, on-site carbon capture solutions for natural gas-based emissions from CHP systems, fuel cells, and boilers. Real-time GHG monitoring plays a crucial role in tracking CO₂ and other emissions removed from the atmosphere through solutions like carbon capture and storage and direct air capture (DAC). [Linkedin](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/)[Envelope](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/). [](https://netzeroinsights.com/resources/move-speed-transition-requires/). [](https://netzeroinsights.com/resources/the-latest-climate-tech-deals-and-funds-29/). [](https://netzeroinsights.com/resources/the-latest-climate-tech-deals-and-funds-28/). [Subscribe Here](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/#). [Continue reading](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/#). [](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/#)[](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/#). [](https://netzeroinsights.com/resources/climate-tech-drives-innovation-in-carbon-removal-and-storage/#).
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siemens-energy.com
article
https://www.siemens-energy.com/global/en/home/products-services/solutions-use…
At Siemens Energy, we believe in the potential of Carbon Capture, Utilization, and Storage (CCUS). CCUS can be added to new build or be retrofitted to existing fossil fuel-based power plants and industrial facilities, capturing CO₂ emissions that would otherwise be released into the atmosphere. Our extensive knowledge of energy systems allows us to work with industry partners to integrate carbon capture technology and create comprehensive CCUS solutions. CCUS is a key technological innovation aimed at reducing atmospheric carbon dioxide (CO₂) emissions. By capturing CO₂ from industrial processes, air and power and heat generation, CCUS prevents this greenhouse gas from impacting climate change. By partnering with leading carbon capture providers, we combine our energy technology and infrastructure expertise with their specialized knowledge to deliver efficient and reliable customized solutions. CCS is a technology that aims to reduce atmospheric carbon dioxide (CO₂) levels by capturing CO₂ from industrial processes and power generation, thereby preventing it from contributing to climate change.
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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.
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ieeexplore.ieee.org
article
https://ieeexplore.ieee.org/document/10585212/
This article examines and evaluates the prominent characteristics of the continuing shift in energy from a higher-carbon to a low-carbon marketplace.
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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).