Molecular dynamics study on the dissociation of methane hydrate via inorganic salts

Hydrate plugging is a hidden threat to the safe exploitation of oil and gas. Inorganic salts are widely used as thermodynamic inhibitors to effectively prevent the hydrate formation. This study uses a molecular dynamics method to explore the mechanism of the hydrate dissociation via inorganic salts on the micro-scale. We simulated the dissociating process of methane hydrate under different concentration series of NaCl, KCl and CaCl₂ solutions at 273 K, and analysed the changes of ionic structure, transport parameters and kinetic energy in the system of inorganic salt/hydrate. The simulation results successfully revealed the step-by-step dissociation of hydrate, and the differences in dissociation rates among the different inhibitors. The energy needed for hydrate dissociation alters for different inorganic solutions; the energy reaches maximum when KCl is the inhibitor, and lowest when the concentration of CaCl₂ exceeds 30% w/w. We calculated the coordination numbers of all components, including oxygen atoms, cations and anions, and also their diffusion coefficients; analysed the effects of the three inorganic salts on the simulated hydrate structure and its transport; in addition, investigated the mechanism of hydrate dissociation via inorganic salts.