Influence of volume ratio of liquid CO2 to seawater on CO2 hydrate sequestration in submarine sediments

doi:10.1016/j.cjche.2025.02.034

中国化学工程学报 ›› 2025, Vol. 85 ›› Issue (9): 327-334.DOI: 10.1016/j.cjche.2025.02.034

Influence of volume ratio of liquid CO₂ to seawater on CO₂ hydrate sequestration in submarine sediments

Minglong Wang¹, Ming Wang¹, Yifei Sun¹, Hongnan Chen¹, Dan Rao¹, Jinrong Zhong², Bei Liu¹, Changyu Sun¹, Guangjin Chen¹

1. College of Chemical Engineering and Environment, China University of Petroleum, Beijing 102249, China;
2. School of Chemistry and Chemical Engineering, Changsha University of Science & Technology, Changsha 410114, China

收稿日期:2024-11-11 修回日期:2024-12-11 接受日期:2025-02-19 出版日期:2025-09-28 发布日期:2025-05-05
通讯作者: Yifei Sun,E-mail:sun.yifei@cup.edu.cn
基金资助:
This work was financially supported by the National Natural Science Foundation of China (22378424, 22127812), the Science Foundation of China University of Petroleum Beijing, China (2462023BJRC017).

Influence of volume ratio of liquid CO₂ to seawater on CO₂ hydrate sequestration in submarine sediments

Minglong Wang¹, Ming Wang¹, Yifei Sun¹, Hongnan Chen¹, Dan Rao¹, Jinrong Zhong², Bei Liu¹, Changyu Sun¹, Guangjin Chen¹

1. College of Chemical Engineering and Environment, China University of Petroleum, Beijing 102249, China;
2. School of Chemistry and Chemical Engineering, Changsha University of Science & Technology, Changsha 410114, China

Received:2024-11-11 Revised:2024-12-11 Accepted:2025-02-19 Online:2025-09-28 Published:2025-05-05
Contact: Yifei Sun,E-mail:sun.yifei@cup.edu.cn
Supported by:
This work was financially supported by the National Natural Science Foundation of China (22378424, 22127812), the Science Foundation of China University of Petroleum Beijing, China (2462023BJRC017).

摘要/Abstract

摘要： CO₂ hydrate-based sequestration in submarine sediments shows great potential for carbon emission reduction. Considering the proportional relationship of CO₂ and water for hydrates formation, their existing ratio largely determines the CO₂ sequestration density and phase state. Here, this work focuses on determining the optimal ratio of CO₂ to seawater in sediments simulated with 20-40 mesh (0.42-0.85 mm) quartz sand, in order to maximize CO₂ hydrate conversion in sediments. The results show that the conversion rate of CO₂ hydrate increases with the initial water saturation, reaching 15.3% at 80% initial water saturation. The optimal CO₂ hydrate formation occurs at 30% initial water saturation, with the corresponding CO₂ storage density in hydrate form of 33.09 kg·m^-3 and the hydrate saturation of 22.3%. However, CO₂ hydrate conversion rate is <10%, which implies that most CO₂ still exists in liquid state, despite the presence of free water. The total CO₂ sequestration density is negatively correlated with the initial water saturation, and at 10% initial water saturation, 398.73 kg·m^-3 of CO₂ is sequestered, of which only 18.02 kg·m^-3 is hydrated. Additionally, the lower initial water saturation corresponds to the shorter time to achieve t₉₀ of CO₂ consumption, and the water conversion rate to hydrate reaches 90% at 10% initial water saturation. In summary, adjusting the volume ratio of liquid CO₂ to seawater can effectively increase the sequestration amount of CO₂ hydrates, but methods to increase CO₂ conversion to hydrate still need to be established.

关键词: CO₂ hydrate, Water content, CO₂ consumption, Storage density, Conversion rate

Abstract: CO₂ hydrate-based sequestration in submarine sediments shows great potential for carbon emission reduction. Considering the proportional relationship of CO₂ and water for hydrates formation, their existing ratio largely determines the CO₂ sequestration density and phase state. Here, this work focuses on determining the optimal ratio of CO₂ to seawater in sediments simulated with 20-40 mesh (0.42-0.85 mm) quartz sand, in order to maximize CO₂ hydrate conversion in sediments. The results show that the conversion rate of CO₂ hydrate increases with the initial water saturation, reaching 15.3% at 80% initial water saturation. The optimal CO₂ hydrate formation occurs at 30% initial water saturation, with the corresponding CO₂ storage density in hydrate form of 33.09 kg·m^-3 and the hydrate saturation of 22.3%. However, CO₂ hydrate conversion rate is <10%, which implies that most CO₂ still exists in liquid state, despite the presence of free water. The total CO₂ sequestration density is negatively correlated with the initial water saturation, and at 10% initial water saturation, 398.73 kg·m^-3 of CO₂ is sequestered, of which only 18.02 kg·m^-3 is hydrated. Additionally, the lower initial water saturation corresponds to the shorter time to achieve t₉₀ of CO₂ consumption, and the water conversion rate to hydrate reaches 90% at 10% initial water saturation. In summary, adjusting the volume ratio of liquid CO₂ to seawater can effectively increase the sequestration amount of CO₂ hydrates, but methods to increase CO₂ conversion to hydrate still need to be established.

Key words: CO₂ hydrate, Water content, CO₂ consumption, Storage density, Conversion rate

Minglong Wang, Ming Wang, Yifei Sun, Hongnan Chen, Dan Rao, Jinrong Zhong, Bei Liu, Changyu Sun, Guangjin Chen. Influence of volume ratio of liquid CO₂ to seawater on CO₂ hydrate sequestration in submarine sediments[J]. 中国化学工程学报, 2025, 85(9): 327-334.

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Influence of volume ratio of liquid CO₂ to seawater on CO₂ hydrate sequestration in submarine sediments

Influence of volume ratio of liquid CO₂ to seawater on CO₂ hydrate sequestration in submarine sediments

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