Abstract
The distribution and diffusion behaviors of microscopic particles at fluorobenzene–water and pentanol–water interfaces are investigated using molecular dynamics simulation. The influences of Na+/Cl− ions and the steric effects of organic molecules are examined. The concentration distributions of different species, the orientations of oil molecules at the interface, and oil–water interface morphology as well as the diffusion behaviors of water molecules are explored and analyzed. The results indicate that a few fluorobenzene molecules move into the water phase influenced by Na+/Cl− ions, while the pentanol molecules at the interface prefer orientating their hydrophilic groups toward the water phase due to their large size. The water molecules more easily burst into the pentanol phase with larger molecular spaces. As the concentration of ions in the water phase increases, more water molecules enter into the pentanol molecules, leading to larger interface roughness and interface thickness. In addition, a lower diffusion coefficient for water molecules at the fluorobenzene–water interface are observed when introducing Na+/Cl− ions in the water phase, while for the pentanol–water system, the mobility of interfacial water molecules are enhanced with less ions and inhibited with more ions.
Highlights
Oil–water interfaces exist widely in physical, chemical, and biological processes, such as interface adsorption [1], extraction [2], emulsification [3,4], phase transfer [5,6], and component transport [7,8].From a microscopic point of view, the particle diffusion at the oil–water interface is simultaneously affected by the same and heterogeneous phases nearby in the interface, presenting distribution and diffusion characteristics that differ from the particles inside the substance
By calculating the mean squared displacement (MSD) curves and diffusion coefficients, it can be seen that adding electrolyte ions can reduce the diffusivity of water molecules in the fluorobenzene–water and pentanol–water systems, which is due to the fact that when electrolyte ions are added, the movement of water molecules overcomes the hydrogen bonding between them, and overcomes the electrostatic interaction exerted by electrolyte ions
The distribution and diffusion behavior of microscopic particles at oil–water two-phase interfaces were studied based on molecular dynamics simulation
Summary
Oil–water interfaces exist widely in physical, chemical, and biological processes, such as interface adsorption [1], extraction [2], emulsification [3,4], phase transfer [5,6], and component transport [7,8]. It was indicated that the electrocatalytic activity of platinum–carbon nanoparticles was closely related to their size and irregular surface These surface/interface analysis techniques are mainly used to analyze and characterize the microscopic characteristics of fixed surfaces/interfaces. Molecular dynamics simulation is performed to study the distribution and diffusion behavior of microscopic particles at the interface of two phases in two oil–water systems of fluorobenzene–water and 1-pentanol–water, which are commonly used in pharmaceutical manufacturing. The effect of adding electrolyte ions (Na+ /Cl− ) to water on the interface morphology and water diffusion characteristics was analyzed in order to provide a clearer understanding of the distribution and diffusion of microscopic particles at the oil–water interface, which provides a theoretical basis for the design and control of physicochemical interface processes in engineering practice
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