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A Comprehensive Review on Carbon Dioxide Sequestration Methods

Author

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  • Gregory Tarteh Mwenketishi

    (School of Engineering, Faculty of Engineering and Digital Technologies, University of Bradford, Bradford BD7 1DP, UK)

  • Hadj Benkreira

    (School of Engineering, Faculty of Engineering and Digital Technologies, University of Bradford, Bradford BD7 1DP, UK)

  • Nejat Rahmanian

    (School of Engineering, Faculty of Engineering and Digital Technologies, University of Bradford, Bradford BD7 1DP, UK)

Abstract

Capturing and storing CO 2 (CCS) was once regarded as a significant, urgent, and necessary option for reducing the emissions of CO 2 from coal and oil and gas industries and mitigating the serious impacts of CO 2 on the atmosphere and the environment. This recognition came about as a result of extensive research conducted in the past. The CCS cycle comes to a close with the last phase of CO 2 storage, which is accomplished primarily by the adsorption of CO 2 in the ocean and injection of CO 2 subsurface reservoir formation, in addition to the formation of limestone via the process of CO 2 reactivity with reservoir formation minerals through injectivities. CCS is the last stage in the carbon capture and storage (CCS) cycle and is accomplished chiefly via oceanic and subterranean geological sequestration, as well as mineral carbonation. The injection of supercritical CO 2 into geological formations disrupts the sub-surface’s existing physical and chemical conditions; changes can occur in the pore fluid pressure, temperature state, chemical reactivity, and stress distribution of the reservoir rock. This paper aims at advancing our current knowledge in CO 2 injection and storage systems, particularly CO 2 storage methods and the challenges encountered during the implementation of each method and analyses on how key uncertainties in CCS can be reduced. CCS sites are essentially unified systems; yet, given the scientific context, these storage systems are typically split during scientific investigations based on the physics and spatial scales involved. Separating the physics by using the chosen system as a boundary condition is a strategy that works effectively for a wide variety of physical applications. Unfortunately, the separation technique does not accurately capture the behaviour of the larger important system in the case of water and gas flow in porous media. This is due to the complexity of geological subsurface systems, which prevents the approach from being able to effectively capture the behaviour of the larger relevant system. This consequently gives rise to different CCS technology with different applications, costs and social and environmental impacts. The findings of this study can help improve the ability to select a suitable CCS application method and can further improve the efficiency of greenhouse gas emissions and their environmental impact, promoting the process sustainability and helping to tackle some of the most important issues that human being is currently accounting global climate change. Though this technology has already had large-scale development for the last decade, some issues and uncertainties are identified. Special attention was focused on the basic findings achieved in CO 2 storage operational projects to date. The study has demonstrated that though a number of CCS technologies have been researched and implemented to date, choosing a suitable and acceptable CCS technology is still daunting in terms of its technological application, cost effectiveness and socio-environmental acceptance.

Suggested Citation

  • Gregory Tarteh Mwenketishi & Hadj Benkreira & Nejat Rahmanian, 2023. "A Comprehensive Review on Carbon Dioxide Sequestration Methods," Energies, MDPI, vol. 16(24), pages 1-42, December.
    • Handle: RePEc:gam:jeners:v:16:y:2023:i:24:p:7971-:d:1296751
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    References listed on IDEAS

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    1. Mahdi Kheirinik & Shaab Ahmed & Nejat Rahmanian, 2021. "Comparative Techno-Economic Analysis of Carbon Capture Processes: Pre-Combustion, Post-Combustion, and Oxy-Fuel Combustion Operations," Sustainability, MDPI, vol. 13(24), pages 1-14, December.
    2. Li, Qi & Wei, Ya-Ni & Liu, Guizhen & Lin, Qing, 2014. "Combination of CO2 geological storage with deep saline water recovery in western China: Insights from numerical analyses," Applied Energy, Elsevier, vol. 116(C), pages 101-110.
    3. Kim, Youngmin & Jang, Hochang & Kim, Junggyun & Lee, Jeonghwan, 2017. "Prediction of storage efficiency on CO2 sequestration in deep saline aquifers using artificial neural network," Applied Energy, Elsevier, vol. 185(P1), pages 916-928.
    4. Procesi, M. & Cantucci, B. & Buttinelli, M. & Armezzani, G. & Quattrocchi, F. & Boschi, E., 2013. "Strategic use of the underground in an energy mix plan: Synergies among CO2, CH4 geological storage and geothermal energy. Latium Region case study (Central Italy)," Applied Energy, Elsevier, vol. 110(C), pages 104-131.
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