Litcius/Paper detail

Ultrafast Formation of Carbon Dioxide Hydrate Foam for Carbon Sequestration

Awan Bhati, Mark Hamalian, Palash V. Acharya, Vaibhav Bahadur

2024ACS Sustainable Chemistry & Engineering15 citationsDOI

Abstract

We report ultrafast formation of carbon dioxide (CO 2 ) hydrate foam without the use of any conventional chemical promoters or mechanical agitation. Our 6× enhancement in the CO 2 sequestration rate (based on net gas consumption) results from the high flow rate sparging of CO 2 gas in water in an open system (constant gas inflow/outflow) in the presence of magnesium. This approach continuously renews the gas–water–hydrate interface, thereby increasing the growth rate. The CO 2 gas consumption rate (for hydrate foam formation) and foam composition (hydrate, CO 2 dissolved in water, trapped CO 2 gas) are experimentally quantified versus various parameters, including thermodynamic (pressure), CO 2 flow-related parameters (flow rate, duration), water composition, and quantity of magnesium. The maximum measured CO 2 sequestration rate (time-averaged) of 1276.5 g h –1 L –1 MPa –1 is 6 times higher than the fastest reported instantaneous rate. Importantly, we show rapid foam formation with saltwater, which will greatly improve the techno-economics. We develop an analytical framework to evaluate the composition of foam. We discover that the reactor pressure is a key determinant of the sequestration rate under high flow rate conditions, with magnesium playing a catalytic role. Overall, such foams enable new approaches to transport and sequester CO 2 and benefit other applications that are hindered by notoriously sluggish hydrate formation.

Topics & Concepts

Carbon sequestrationCarbon dioxideCarbon nanofoamClathrate hydrateHydrateChemical engineeringNegative carbon dioxide emissionCarbon fibersChemistryMaterials scienceWaste managementOrganic chemistryPorosityComposite materialComposite numberEngineeringMethane Hydrates and Related PhenomenaCO2 Sequestration and Geologic InteractionsHydrocarbon exploration and reservoir analysis