• Title of article

    The interfacial dynamics of water sandwiched between graphene sheets are governed by the slit width

  • Author/Authors

    Deshmukh، نويسنده , , Sanket A. and Kamath، نويسنده , , Ganesh and Baker، نويسنده , , Gary A. and Sumant، نويسنده , , Anirudha V. and Sankaranarayanan، نويسنده , , Subramanian K.R.S.، نويسنده ,

  • Issue Information
    هفته نامه با شماره پیاپی سال 2013
  • Pages
    11
  • From page
    129
  • To page
    139
  • Abstract
    Atomic scale characterization and fluxional properties of water molecules in the vicinity of the graphene interface is carried out using molecular dynamics (MD) simulations. The structural properties of proximal water molecules near the graphene interface are strongly correlated to their vibrational densities of states while being studied as a function of the slit width of the graphene sheets. Our simulations indicate that the local orientation, ordering and solvation dynamics of interfacial water molecules are a strong function of the graphene slit width. Systematic trends in libration, bending, and stretching bands are correlated with local ordering of water molecules and hydrogen-bonding network. Smaller blue shifts in the intermolecular O…O…O bending mode and larger blue shifts in the O…O intermolecular stretching modes of water molecules are observed for strongly confined water molecules in comparison to bulk water, which is attributed to the interfacial proximity effects resulting in the restricted transverse oscillations of confined water. The O―H stretching band is red-shifted for confined water in comparison to bulk water whereas the libration and bending bands for interfacial water are blue shifted with respect to bulk water. The observed frequency shifts are a consequence of the distortion of the tetrahedral order in confined water caused by lateral diffusion being reduced and also by changes in the distribution of hydrogen bonds. These simulations suggest that the extent of the shifts of confined water in comparison to bulk water are due to the proximity from the hydrophobic surface, their local confinement and hydrogen bonding status.
  • Keywords
    Interfacial dynamics , Hydrohobic surface , Molecular dynamics
  • Journal title
    Surface Science
  • Serial Year
    2013
  • Journal title
    Surface Science
  • Record number

    1705650