Abstract

Hydrate-based CO₂ storage is a highly promising technology for long-term stable CO₂ storage in sediments. However, the unclear displacement and hydration mechanisms, along with the low conversion rate of CO₂ hydrates, have hindered the field application. Here, we report a method of the injection of CO₂/water emulsion to replace liquid CO₂ to regulate the ratio of CO₂ to water in the sediment pores and to enhance their contact ability, which can significantly improve the CO₂ hydrate conversion rate. Compared to liquid CO₂ injection, emulsion injection can flow through more sediment pores with an increase in displacement efficiency by 45?%-62?%, which leaves a CO₂-to-water ratio within the pores that is more suitable for hydrate formation, ultimately tripling the hydrate conversion rate. We have outlined the hydrate growth mechanisms for both injection forms, where the micron-sized CO₂ droplets within the emulsion can greatly reduce the barrier effect of hydrate film. Under the combined influences, the CO₂ storage density in hydrates up to 91.2 kg/m³ for CO₂/water emulsion injection is 47.8?% higher than that of 61.7?kg/m³ for liquid CO₂ injection. Our work provides a new approach to high conversion CO₂ hydrate sequestration in submarine sediments.