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Technologies and infrastructures underpinning future CO2 value chains: A comprehensive review and comparative analysis

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  • Jarvis, Sean M.
  • Samsatli, Sheila

Abstract

In addition to carbon capture and storage, efforts are also being focussed on using captured CO2, both directly as a working fluid and in chemical conversion processes, as a key strategy for mitigating climate change and achieving resource efficiency. These processes require large amounts of energy, which should come from sustainable and, ideally, renewable sources. A strong value chain is required to support the production of valuable products from CO2. A value chain is a network of technologies and infrastructures (such as conversion, transportation, storage) along with its associated activities (such as sourcing raw materials, processing, logistics, inventory management, waste management) required to convert low-value resources to high-value products and energy services, and deliver them to customers. A CO2 value chain involves production of CO2 (involving capture and purification), technologies that convert CO2 and other materials into valuable products, sourcing of low-carbon energy to drive all of the transformation processes required to convert CO2 to products (including production of hydrogen, syngas, methane etc.), transport of energy and materials to where they are needed, managing inventory levels of resources, and delivering the products to customers, all in order to create value (economic, environmental, social etc.).

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  • Jarvis, Sean M. & Samsatli, Sheila, 2018. "Technologies and infrastructures underpinning future CO2 value chains: A comprehensive review and comparative analysis," Renewable and Sustainable Energy Reviews, Elsevier, vol. 85(C), pages 46-68.
  • Handle: RePEc:eee:rensus:v:85:y:2018:i:c:p:46-68
    DOI: 10.1016/j.rser.2018.01.007
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    2. Samsatli, Sheila & Samsatli, Nouri J., 2019. "The role of renewable hydrogen and inter-seasonal storage in decarbonising heat – Comprehensive optimisation of future renewable energy value chains," Applied Energy, Elsevier, vol. 233, pages 854-893.
    3. Ryoo, Seung Gul & Jung, Han Sol & Kim, MinJae & Kang, Yong Tae, 2021. "Bridge to zero-emission: Life cycle assessment of CO2–methanol conversion process and energy optimization," Energy, Elsevier, vol. 229(C).
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    6. Ravikumar, Dwarakanath & Keoleian, Gregory & Miller, Shelie, 2020. "The environmental opportunity cost of using renewable energy for carbon capture and utilization for methanol production," Applied Energy, Elsevier, vol. 279(C).
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    8. Quarton, Christopher J. & Samsatli, Sheila, 2018. "Power-to-gas for injection into the gas grid: What can we learn from real-life projects, economic assessments and systems modelling?," Renewable and Sustainable Energy Reviews, Elsevier, vol. 98(C), pages 302-316.
    9. Hermesmann, M. & Grübel, K. & Scherotzki, L. & Müller, T.E., 2021. "Promising pathways: The geographic and energetic potential of power-to-x technologies based on regeneratively obtained hydrogen," Renewable and Sustainable Energy Reviews, Elsevier, vol. 138(C).
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    13. Paulsen, M.M. & Petersen, S.B. & Lozano, E.M. & Pedersen, T.H., 2024. "Techno-economic study of integrated high-temperature direct air capture with hydrogen-based calcination and Fischer–Tropsch synthesis for jet fuel production," Applied Energy, Elsevier, vol. 369(C).
    14. Pavel Tcvetkov, 2021. "Climate Policy Imbalance in the Energy Sector: Time to Focus on the Value of CO 2 Utilization," Energies, MDPI, vol. 14(2), pages 1-22, January.
    15. Tapia, John Frederick D., 2021. "Optimal synthesis of multi-product energy systems under neutrosophic environment," Energy, Elsevier, vol. 229(C).
    16. Mikulčić, Hrvoje & Ridjan Skov, Iva & Dominković, Dominik Franjo & Wan Alwi, Sharifah Rafidah & Manan, Zainuddin Abdul & Tan, Raymond & Duić, Neven & Hidayah Mohamad, Siti Nur & Wang, Xuebin, 2019. "Flexible Carbon Capture and Utilization technologies in future energy systems and the utilization pathways of captured CO2," Renewable and Sustainable Energy Reviews, Elsevier, vol. 114(C), pages 1-1.
    17. Philipp C. Verpoort & Lukas Gast & Anke Hofmann & Falko Ueckerdt, 2024. "Impact of global heterogeneity of renewable energy supply on heavy industrial production and green value chains," Nature Energy, Nature, vol. 9(4), pages 491-503, April.
    18. Dea Hyun Moon & Jun Eu & Wonhee Lee & Young Eun Kim & Ki Tae Park & You Na Ko & Soon Kwan Jeong & Min Hye Youn, 2020. "Comparison of reactions with different calcium sources for CaCO3 production using carbonic anhydrase," Greenhouse Gases: Science and Technology, Blackwell Publishing, vol. 10(5), pages 898-906, October.
    19. Ismail Ismail & Vassilis Gaganis, 2023. "Carbon Capture, Utilization, and Storage in Saline Aquifers: Subsurface Policies, Development Plans, Well Control Strategies and Optimization Approaches—A Review," Clean Technol., MDPI, vol. 5(2), pages 1-29, May.
    20. Mohammed Bin Afif & Abdulla Bin Afif & Harry Apostoleris & Krishiv Gandhi & Anup Dadlani & Amal Al Ghaferi & Jan Torgersen & Matteo Chiesa, 2022. "Ultra-Cheap Renewable Energy as an Enabling Technology for Deep Industrial Decarbonization via Capture and Utilization of Process CO 2 Emissions," Energies, MDPI, vol. 15(14), pages 1-15, July.
    21. Abdulrasheed, Abdulrahman & Jalil, Aishah Abdul & Gambo, Yahya & Ibrahim, Maryam & Hambali, Hambali Umar & Shahul Hamid, Muhamed Yusuf, 2019. "A review on catalyst development for dry reforming of methane to syngas: Recent advances," Renewable and Sustainable Energy Reviews, Elsevier, vol. 108(C), pages 175-193.
    22. Li, Chengzhe & Zhang, Libo & Ou, Zihan & Ma, Jiayu, 2022. "Using system dynamics to evaluate the impact of subsidy policies on green hydrogen industry in China," Energy Policy, Elsevier, vol. 165(C).

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