Abstract
Surface properties of room temperature ionic liquids (RTILs) consisting of half neutralized diamine cations (H2N-(CH2)n-NH3+, n = 2, 4) and triflate anions have been investigated by molecular dynamics simulations, based on an empirical atomistic force field. Planar slabs periodically repeated in 2D have been considered, and the temperature range 260 ≤ T ≤ 360 K has been covered, extending from below the melting and glass point to the equilibrium liquid range of the diamine compounds under investigation. Addition of water at 1% weight concentration allowed us to investigate the kinetics of water absorption through the RTIL surface, and to characterize the structural and dynamical properties of subsurface water. Animations of the simulation trajectory highlight the quick absorption of water molecules, progressing downhill in free energy and taking place without apparent intermediate kinetic stages. To verify and quantify these observations, a variant of the umbrella sampling algorithm has been applied to compute the variation of excess free energy upon displacing a water molecule along the normal to the surface, from the center of the slab to the vapor phase. The results provide a comprehensive picture of the thermodynamic properties underlying the kinetics of water absorption and evaporation through the surface, and they also provide the ratio of the equilibrium density of water in the vapor and liquid phase at the average concentration considered by simulations. A variety of properties such as the surface energy, the 90-10% width of the profile, the layering of different species at the interface, and the electrostatic double layer at the surface are computed and discussed, focusing on the effect of water contamination on all of them.
Highlights
Organic ionic compounds of low melting temperature (Tm ≤ 373 K) known as room-temperature ionic liquids[1,2] (RTILs) summarize in themselves properties such as the low volatility and high thermal and chemical stability of ionic systems, together with the wide range of sizes, modular structure, and low melting point of organic molecules.[3,4] At least in their most popular manifestations, room temperature ionic liquids (RTILs) present low toxicity and moderate environmental impact,[5] and their selective affinity for biomolecules[6] opens the way to future applications in pharmacology[7] and biomedicine.[8]
Surface properties of room temperature ionic liquids (RTILs) consisting of half neutralized diamine cations (H2N−(CH2)n−NH3+, n = 2, 4) and triflate anions have been investigated by molecular dynamics simulations, based on an empirical atomistic force field
Planar slabs periodically repeated in 2D have been considered, and the temperature range 260 ≤ T ≤ 360 K has been covered, extending from below the melting and glass point to the equilibrium liquid range of the diamine compounds under investigation
Summary
Organic ionic compounds of low melting temperature (Tm ≤ 373 K) known as room-temperature ionic liquids[1,2] (RTILs) summarize in themselves properties such as the low volatility and high thermal and chemical stability of ionic systems, together with the wide range of sizes, modular structure, and low melting point of organic molecules.[3,4] At least in their most popular manifestations, RTILs present low toxicity and moderate environmental impact,[5] and their selective affinity for biomolecules[6] opens the way to future applications in pharmacology[7] and biomedicine.[8]. Protic ionic liquids[11−13] (PILs) represent a special class of RTILs that can be synthesized by neutralizing a Brønsted acid with a Lewis base. PILs, in general, share the positive properties as well as the limitations of other classes of ionic liquids, but the acidic proton that gives them their name sometimes displays enhanced mobility, due to proton-specific mechanisms such as Grotthuss conductivity.[14] The improved ion conductivity, in turn, makes selected PILs suitable for applications in electrochemistry,[15] favored by the wide electrochemical window of these compounds
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