A review on materials and processes for carbon dioxide separation and capture

Maniarasu, R.; Rathore, Sushil Kumar; Murugan, S.

doi:10.1177/0958305x211050984

Cited by 17 publications

(4 citation statements)

References 84 publications

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“…According to the differences in these absorbents, the common physical absorption methods in the industry include Rectisol, Selexol, and Fluor, etc. Table 1 summarizes their industrial applications and respective advantages [37]. Limitations: Higher viscosity than most physical solvents.…”

Section: Physical Absorption Methodsmentioning

confidence: 99%

The Efficient Utilization of Carbon Dioxide in a Power-to-Liquid Process: An Overview

Zhang

et al. 2023

Processes

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As the global climate crisis escalates, reductions in CO2 emissions and the efficient utilization of carbon waste resources have become a crucial consensus. Among the various carbon mitigation technologies, the concept of power-to-liquid (PTL) has gained significant attention in recent years. Considering the lack of a timely review of the state-of-the-art progress of this PTL process, this work aims to provide a systematic summary of the advanced PTL progress. In a CO2 capture unit, we compared the process performances of chemical absorption, physical absorption, pressure swing adsorption, and membrane separation technologies. In a water electrolysis unit, the research progress of alkaline water electrolysis, proton exchange membrane water electrolysis, and solid oxide water electrolysis technologies was summarized, and the strategies for improving the electrolysis efficiency were proposed. In a CO2 hydrogenation unit, we compared the differences of high-temperature and low-temperature Fischer–Tropsch synthesis processes, and summarized the advanced technologies for promoting the conversion of CO2 into high value-added hydrocarbons and achieving the efficient utilization of C1–C4 hydrocarbons. In addition, we critically reviewed the technical and economic performances of the PTL process. By shedding light on the current state of research and identifying its crucial factors, this work is conducive to enhancing the understanding of the PTL process and providing reliable suggestions for its future industrial application. By offering valuable insights into the PTL process, this work also contributes to paving the way for the development of more efficient and sustainable solutions to address the pressing challenges of CO2 emissions and climate change.

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Section: Physical Absorption Methodsmentioning

confidence: 99%

The Efficient Utilization of Carbon Dioxide in a Power-to-Liquid Process: An Overview

Zhang

et al. 2023

Processes

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“…Additionally, the integration of water-gas shift (WGS) reactors and CO2 capture units into the gasification process streamlines the overall capture process and minimizes energy penalties. Another best practice in pre-combustion capture is the utilization of advanced CO2 separation techniques, such as pressure swing adsorption (PSA) and membrane separation, to achieve high-purity CO2 streams with minimal energy consumption (Maniarasu et al, 2023;Ekechi et al, 2024). PSA systems utilize adsorbents such as zeolites or activated carbons to selectively adsorb CO2 from the syngas stream under high pressure, while membrane separation relies on permeable membranes to selectively transport CO2 molecules across a membrane barrier.…”

Section: Best Practices In Co2 Capturementioning

confidence: 99%

Best practices and innovations in carbon capture and storage (CCS) for effective CO2 storage

Andrew Emuobosa Esiri,

Dazok Donald Jambol,

Chinwe Ozowe

2024

Int. j. appl. res. soc. sci.

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Carbon capture and storage (CCS) has emerged as a critical technology in the fight against climate change, offering a viable pathway to mitigate CO2 emissions from industrial processes and power generation. This review explores the best practices and innovations in CCS for effective CO2 storage, highlighting key strategies and advancements that optimize storage capacity, enhance storage security, and minimize environmental risks. The review begins by delineating the importance of CCS in reducing greenhouse gas emissions and meeting global climate targets. It underscores the urgency of deploying CCS technologies at scale to address the dual challenge of decarbonizing energy systems and ensuring energy security. Drawing upon recent research and industry developments, the review elucidates best practices in CO2 capture, transport, and storage, emphasizing the importance of integrated and holistic approaches. It discusses advancements in CO2 capture technologies, including post-combustion capture, pre-combustion capture, and oxy-fuel combustion, highlighting efficiency improvements and cost reduction strategies. Furthermore, the review delves into innovations in CO2 storage techniques, such as geological storage, ocean storage, and mineralization, evaluating their respective advantages, challenges, and scalability. It explores best practices for site selection, characterization, and monitoring, emphasizing the need for robust risk assessment frameworks and regulatory oversight to ensure the safety and integrity of storage sites. Moreover, the review examines emerging trends and innovations in CCS, including enhanced oil recovery (EOR) using CO2, direct air capture (DAC) technologies, and carbon utilization and storage (CCUS) initiatives. It discusses the potential synergies between CCS and renewable energy technologies, highlighting integrated solutions that leverage CCS to enable the decarbonization of hard-to-abate sectors such as heavy industry and aviation. The review underscores the pivotal role of CCS in achieving deep decarbonization and transitioning to a low-carbon economy. It calls for continued research, investment, and collaboration to unlock the full potential of CCS technologies and accelerate their deployment at scale. By embracing best practices and fostering innovation, stakeholders can pave the way for effective CO2 storage and contribute to global efforts to combat climate change. Keywords: Best Practices, Innovation, Carbon, Capture, Storage, CO2.

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“…The feed gas is supplied to a solid adsorbent surface, which selectively adsorbs CO2 until equilibrium is reached. Active adsorbents include CaO, alkali silicates, zeolites, carbon activated, carbon nanotubes, carbon nanofibers, graphene, and molecular sieves [31,32]. Adsorbents can be regenerated through vacuum-swing adsorption, pressure-swing adsorption, or a combination of vacuum-pressure swing adsorption [33].…”

Section: Adsorptionmentioning

confidence: 99%

The most effective techniques of industrial purification processes: a technical review

Saud,

AlJaberi

2023

Chim.Tech.Acta

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This paper reviews various separation techniques used in purification processes to remove pollutants like carbon dioxide and hydrogen sulfide from petroleum products. The most effective techniques include absorption, adsorption, cryogenic distillation, chemical looping combustion, and membrane separation. The study reviews over 100 published studies to assess their characteristics, benefits, and drawbacks. The choice of separation technology depends on ideal conditions, cost, efficiency, and energy required in the regeneration phase.

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A review on materials and processes for carbon dioxide separation and capture

Cited by 17 publications

References 84 publications

The Efficient Utilization of Carbon Dioxide in a Power-to-Liquid Process: An Overview

The Efficient Utilization of Carbon Dioxide in a Power-to-Liquid Process: An Overview

Best practices and innovations in carbon capture and storage (CCS) for effective CO2 storage

The most effective techniques of industrial purification processes: a technical review

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