Abstract
Most reported slip length measurements have been made at the surfaces of synthetic materials and modified synthetic materials. In contrast, few slip length measurements at the surface of unmodified natural mineral surfaces have been reported. In this regard, flow at the silica face surfaces of the phyllosilicate minerals, talc and mica, was considered. A slip boundary condition was expected at the nonpolar hydrophobic silica surface of talc leading to enhanced flow, and a no-slip boundary condition was expected at the hydrophilic silica surface of mica. Atomic force microscopy (AFM) slip length measurements were made at the talc and mica surfaces. The slip length results for the hydrophobic silica surface of talc were contrasted to the results for the hydrophilic silica surface of mica (no-slip flow). The results are discussed based on molecular dynamics simulations (MDS), as reported in the literature, and AFM images of surface nanobubbles. For nonpolar hydrophobic surfaces (such as talc), it is doubtful that the MDS interfacial water structure and the water exclusion zone (3.2 Å) account for the AFM slip flow with slip lengths as great as 95 nm. Rather, a better explanation for the AFM slip flow condition is based on reduced interfacial viscosity due to the presence of dissolved gas and the accommodation of pancake nanobubbles at the talc surface having a height dimension of magnitude similar to the slip length.
Highlights
The liquid flow behavior in nanoscale pores is of interest in the fields of oil and gas recovery, energy storage [1], water purification [2] and nano-filtration [3]
The results reported in the literature, including both experimental and theoretical research, have shown that the flow of water in hydrophobic nanopores is enhanced compared to that predicted by the no-slip boundary condition of the Hagen-Poiseuille (HP) law [4,5,6]
The enhanced water flow is described by the boundary slip condition, which is determined by many physical characteristics of the system, including pore wall interactions with water molecules, pore wall surface roughness, shear rate, gas films or nanobubbles, viscosity, temperature, pore dimensions, and pressure gradient
Summary
The liquid flow behavior in nanoscale pores is of interest in the fields of oil and gas recovery, energy storage [1], water purification [2] and nano-filtration [3]. The results reported in the literature, including both experimental and theoretical research, have shown that the flow of water in hydrophobic nanopores is enhanced compared to that predicted by the no-slip boundary condition of the Hagen-Poiseuille (HP) law [4,5,6]. The enhanced water flow is described by the boundary slip condition, which is determined by many physical characteristics of the system, including pore wall interactions with water molecules (which can be described by wettability and/or contact angle measurements at the wall surface), pore wall surface roughness, shear rate, gas films or nanobubbles, viscosity, temperature, pore dimensions, and pressure gradient. The boundary condition is one of the most critical factors that determines the mechanics of water flow. The slip length and flow enhancement factors have been determined experimentally and from theory [4,5,6,7]
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