By incorporating cation-π interactions to classic all-atoms force fields, we show that there is a clear enrichment of Na+ on a carbon-based π electron-rich surface in NaCl solutions using molecular dynamics simulations. Interestingly, Cl− is also enriched to some extend on the surface due to the electrostatic interaction between Na+ and Cl−, although the hydrated Cl−-π interaction is weak. The difference of the numbers of Na+ and Cl− accumulated at the interface leads to a significant negatively charged behavior in the solution, especially in nanoscale systems. Moreover, we find that the accumulation of the cations at the interfaces is universal since other cations (Li+, K+, Mg2+, Ca2+, Fe2+, Co2+, Cu2+, Cd2+, Cr2+, and Pb2+) have similar adsorption behaviors. For comparison, as in usual force field without the proper consideration of cation-π interactions, the ions near the surfaces have a similar density of ions in the solution.
Combining classical molecular dynamics simulations and density functional theory calculations, we find that cations block water flow through narrow (6,6)-type carbon nanotubes (CNTs) because of interactions between cations and aromatic rings in CNTs. In wide CNTs, these interactions trap the cations in the interior of the CNT, inducing unexpected open or closed state switching of ion transfer under a strong electric field, which is consistent with experiments. These findings will help to develop new methods to facilitate water and ion transport across CNTs.
The structure of the water chain in the 8 x cyclo-(WL)(4) peptide nanotube embedded in the POPE lipid bilayer is studied by molecular dynamics simulations. The distribution profiles of water molecules along the nanotube axis proposes a wavelike pattern of the water chain in the nanotube, arraying in the form of a 1-2-1-2 file, in contrast to the single file in other nanochannels studied widely. Cylindrical distribution functions of water at different zones and potential of mean force of a water molecule along the axis suggest that the primary reason for forming the water-chain pattern is steric constraints. A novel hydrogen bond network in the nanotube is present such that each water in the alpha-plane zones forms two hydrogen bonds (as a donor) with the two water molecules in the adjacent midplane zone, and each water molecule in the midplane zones forms one hydrogen bond with the water molecule in the adjacent alpha-plane zone and a poor hydrogen bond with the carbonyl groups in the nanotube. Strong orientations of the water dipoles near the two opening ends pointing to the opposite directions are found, and the potential energy of a water O or H atom along the axis is explored to explain the water dipole orientations' reversing in the nanotube. Defects of the hydrogen bond network exist in the central gaps of the cyclic peptide nanotube.
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