Min Chen scite author profile

Molecular dynamics simulations have been carried out to investigate the fluid wetting and flow in nanochannels whose surfaces are structured by an array of nanoscale triangular modules. We find that the surface nanostructures have a dual effect on the boundary slip and friction of the liquid nanoflow. On the one hand, the nanostructures can enhance the surface hydrophilicity for a hydrophilic liquid-solid interaction, and can increase the hydrophobicity for a hydrophobic interaction due to a nanoscale lotus effect. In particular, the nanostructured surface may show superhydrophobicity and lead to the large velocity slip of the liquid flow. On the other hand, simultaneously, the nanostructures distort the nanoscale streamlines of the liquid flow near the channel surfaces and block the nanoflow directly, which decreases the apparent slip length equivalently. The dual effect of the nanostructures on the surface wettability and the hydrodynamic disturbance results in a nonmonotonic dependence of the slip length on the nanostructure size. The simulations imply that the surface nanostructures can be applied to control the friction of liquid micro-and nanoflows.

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Effect of surface roughness on gas flow in microchannels by molecular dynamics simulation

Cao

Chen

Zhang

2006

International Journal of Engineering Science

156

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Molecular dynamics simulation on evaporation of water and aqueous droplets in the presence of electric field

Wang

Duan

et al. 2014

International Journal of Heat and Mass Transfer

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Min Chen

High-order multiphoton Thomson scattering

Oblique Interaction of Solitary Waves

Liquid flow in surface-nanostructured channels studied by molecular dynamics simulation

Effect of surface roughness on gas flow in microchannels by molecular dynamics simulation

Molecular dynamics simulation on evaporation of water and aqueous droplets in the presence of electric field

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