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Carbon Capture and Utilization in the Industrial Sector

Author

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  • Psarras, Peter C.

    (Colorado School of Mines)

  • Comello, Stephen

    (Stanford University)

  • Bains, Praveen

    (Stanford University)

  • Charoensawadpong, Panunya

    (Stanford University)

  • Reichelstein, Stefan J.

    (Stanford University)

  • Wilcox, Jennifer

    (Colorado School of Mines)

Abstract

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 is important given that this sector accounts for 23% of total global emissions. 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. Further, we find truck transportation is generally the low-cost alternative compared to pipeline transport for small volumes indicative of this kind of capture activity (100 kt CO2/a). We apply this methodology to a regional case study, which shows steel and cement manufacturing as having the lowest levelized cost of abatement.

Suggested Citation

  • Psarras, Peter C. & Comello, Stephen & Bains, Praveen & Charoensawadpong, Panunya & Reichelstein, Stefan J. & Wilcox, Jennifer, 2017. "Carbon Capture and Utilization in the Industrial Sector," Research Papers repec:ecl:stabus:3493, Stanford University, Graduate School of Business.
    • Handle: RePEc:ecl:stabus:repec:ecl:stabus:3493
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    Cited by:

    1. Yagihara, Koki & Ohno, Hajime & Guzman-Urbina, Alexander & Ni, Jialing & Fukushima, Yasuhiro, 2022. "Analyzing flue gas properties emitted from power and industrial sectors toward heat-integrated carbon capture," Energy, Elsevier, vol. 250(C).
    2. McLaughlin, Hope & Littlefield, Anna A. & Menefee, Maia & Kinzer, Austin & Hull, Tobias & Sovacool, Benjamin K. & Bazilian, Morgan D. & Kim, Jinsoo & Griffiths, Steven, 2023. "Carbon capture utilization and storage in review: Sociotechnical implications for a carbon reliant world," Renewable and Sustainable Energy Reviews, Elsevier, vol. 177(C).
    3. Patange, Omkar S. & Garg, Amit & Jayaswal, Sachin, 2022. "An integrated bottom-up optimization to investigate the role of BECCS in transitioning towards a net-zero energy system: A case study from Gujarat, India," Energy, Elsevier, vol. 255(C).
    4. Choi, Sung & Park, Jungjoon & Kang, Yong Tae, 2019. "Experimental investigation on CO2 hydrate formation/dissociation for cold thermal energy harvest and transportation applications," Applied Energy, Elsevier, vol. 242(C), pages 1358-1368.
    5. Tsay, Calvin & Pattison, Richard C. & Zhang, Yue & Rochelle, Gary T. & Baldea, Michael, 2019. "Rate-based modeling and economic optimization of next-generation amine-based carbon capture plants," Applied Energy, Elsevier, vol. 252(C), pages 1-1.
    6. Guillermo Martinez Castilla & Diana Carolina Guío-Pérez & Stavros Papadokonstantakis & David Pallarès & Filip Johnsson, 2021. "Techno-Economic Assessment of Calcium Looping for Thermochemical Energy Storage with CO 2 Capture," Energies, MDPI, vol. 14(11), pages 1-17, May.
    7. Gür, Turgut M., 2020. "Perspectives on oxygen-based coal conversion towards zero-carbon power generation," Energy, Elsevier, vol. 196(C).
    8. Shao, Tianming & Pan, Xunzhang & Li, Xiang & Zhou, Sheng & Zhang, Shu & Chen, Wenying, 2022. "China's industrial decarbonization in the context of carbon neutrality: A sub-sectoral analysis based on integrated modelling," Renewable and Sustainable Energy Reviews, Elsevier, vol. 170(C).
    9. Huang, Yi & Yi, Qun & Kang, Jing-Xian & Zhang, Ya-Gang & Li, Wen-Ying & Feng, Jie & Xie, Ke-Chang, 2019. "Investigation and optimization analysis on deployment of China coal chemical industry under carbon emission constraints," Applied Energy, Elsevier, vol. 254(C).
    10. Ramirez-Corredores, M.M. & Diaz, Luis A. & Gaffney, Anne M. & Zarzana, Christopher A., 2021. "Identification of opportunities for integrating chemical processes for carbon (dioxide) utilization to nuclear power plants," Renewable and Sustainable Energy Reviews, Elsevier, vol. 150(C).
    11. Fan, Jing-Li & Shen, Shuo & Wei, Shi-Jie & Xu, Mao & Zhang, Xian, 2020. "Near-term CO2 storage potential for coal-fired power plants in China: A county-level source-sink matching assessment," Applied Energy, Elsevier, vol. 279(C).
    12. Waxman, Andrew R. & Corcoran, Sean & Robison, Andrew & Leibowicz, Benjamin D. & Olmstead, Sheila, 2021. "Leveraging scale economies and policy incentives: Carbon capture, utilization & storage in Gulf clusters," Energy Policy, Elsevier, vol. 156(C).
    13. Fikru, Mahelet G. & Azure, Jessica W.A., 2023. "Renewable energy technologies and carbon capture retrofits are strategic complements," Technological Forecasting and Social Change, Elsevier, vol. 196(C).
    14. Shuai Nie & Guotian Cai & Yixuan Li & Yushu Chen & Ruxue Bai & Liping Gao & Xiaoyu Chen, 2022. "To Adopt CCU Technology or Not? An Evolutionary Game between Local Governments and Coal-Fired Power Plants," Sustainability, MDPI, vol. 14(8), pages 1-18, April.
    15. Golrokh Sani, Ahmad & Najafi, Hamidreza & Azimi, Seyedeh Shakiba, 2022. "Dynamic thermal modeling of the refrigerated liquified CO2 tanker in carbon capture, utilization, and storage chain: A truck transport case study," Applied Energy, Elsevier, vol. 326(C).

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