Litcius/Paper detail

The behavior of methane–water mixtures under elevated pressures from simulations using many-body potentials

Victor Naden Robinson, Raja Ghosh, Colin K. Egan, Marc Riera, Chris Knight, Francesco Paesani, Ali Hassanali

2022The Journal of Chemical Physics18 citationsDOIOpen Access PDF

Abstract

Non-polarizable empirical potentials have been proven to be incapable of capturing the mixing of methane-water mixtures at elevated pressures. Although density functional theory-based ab initio simulations may circumvent this discrepancy, they are limited in terms of the relevant time and length scales associated with mixing phenomena. Here, we show that the many-body MB-nrg potential, designed to reproduce methane-water interactions with coupled cluster accuracy, successfully captures this phenomenon up to 3 GPa and 500 K with varying methane concentrations. Two-phase simulations and long time scales that are required to fully capture the mixing, affordable due to the speed and accuracy of the MBX software, are assessed. Constructing the methane-water equation of state across the phase diagram shows that the stable mixtures are denser than the sum of their parts at a given pressure and temperature. We find that many-body polarization plays a central role, enhancing the induced dipole moments of methane by 0.20 D during mixing under pressure. Overall, the mixed system adopts a denser state, which involves a significant enthalpic driving force as elucidated by a systematic many-body energy decomposition analysis.

Topics & Concepts

MethaneMixing (physics)DipolePolarizabilityChemistryThermodynamicsAb initioChemical physicsPhysicsMoleculeOrganic chemistryQuantum mechanicsHigh-pressure geophysics and materialsQuantum, superfluid, helium dynamicsMethane Hydrates and Related Phenomena