Solubility of carbon dioxide in water: Some useful results for hydrate nucleation

Abstract: In this paper, the solubility of carbon dioxide (CO2) in water along the isobar of 400 bar is determined by computer simulations using the well-known TIP4P/Ice force field for water and the TraPPE model for CO2. In particular, the solubility of CO2 in water when in contact with the CO2 liquid phase and the solubility of CO2 in water when in contact with the hydrate have been determined. The solubility of CO2 in a liquid–liquid system decreases as the temperature increases. The solubility of CO2 in a hydrate–li… Show more

“…Because the nucleation of CO 2 hydrate is affected by the dissolution of carbon dioxide, 48 the higher the concentration of CO 2 is, the more favorable the nucleation of CO 2 hydrates. Therefore, when the gas−liquid ratio reaches its maximum value, the amount of CO 2 dissolved in water is the least, and the magnitude of the pressure drop is relatively low.…”

“…Furthermore, when the same molar amount of CO 2 was dissolved in water, the smaller the gas–liquid ratio, the more significant the pressure drop and the lower the CO 2 concentration in water. Because the nucleation of CO 2 hydrate is affected by the dissolution of carbon dioxide, the higher the concentration of CO 2 is, the more favorable the nucleation of CO 2 hydrates. Therefore, when the gas–liquid ratio reaches its maximum value, the amount of CO 2 dissolved in water is the least, and the magnitude of the pressure drop is relatively low.…”

Experimental Study on the Influence of the Temperature and Gas–Liquid Ratio on Hydrate-Based CO₂ Separation from the CH₄–CO₂ Gas Mixture under Static Conditions

“…Because the nucleation of CO 2 hydrate is affected by the dissolution of carbon dioxide, 48 the higher the concentration of CO 2 is, the more favorable the nucleation of CO 2 hydrates. Therefore, when the gas−liquid ratio reaches its maximum value, the amount of CO 2 dissolved in water is the least, and the magnitude of the pressure drop is relatively low.…”

“…Furthermore, when the same molar amount of CO 2 was dissolved in water, the smaller the gas–liquid ratio, the more significant the pressure drop and the lower the CO 2 concentration in water. Because the nucleation of CO 2 hydrate is affected by the dissolution of carbon dioxide, the higher the concentration of CO 2 is, the more favorable the nucleation of CO 2 hydrates. Therefore, when the gas–liquid ratio reaches its maximum value, the amount of CO 2 dissolved in water is the least, and the magnitude of the pressure drop is relatively low.…”

Experimental Study on the Influence of the Temperature and Gas–Liquid Ratio on Hydrate-Based CO₂ Separation from the CH₄–CO₂ Gas Mixture under Static Conditions

“…Although energetics align (critical nucleus size and interfacial free energies), significant differences in dynamical properties (characteristic nucleation time and growth rate) impact the kinetics of crystallization, resulting in different characteristics of crystalline nuclei and methane concentration dependencies between the two models. Algaba et al 22 employ computer simulations to determine the solubility of carbon dioxide (CO 2 ) in water under conditions relevant to hydrate nucleation. Using the TIP4P/Ice and TraPPE models for water and CO 2 , respectively, the simulations show that the solubility of CO 2 in water when in contact with liquid CO 2 decreases with temperature, while it increases with temperature in a hydrate-liquid water system.…”

Special Topic Preface: Nucleation—Current understanding approaching 150 years after Gibbs

The morphology of liquid CO2 hydrate films at different temperatures under saturation pressure