We use molecular dynamics simulations to study thermal sliding of two nanostructured surfaces separated by nanoscale water films. We find that friction at molecular separations is determined primarily by the effective free energy landscape for motion in the plane of sliding, which depends sensitively on the surface character and the molecular structure of the confined water. Small changes in the surface nanostructure can have dramatic effects on the apparent rheology. Whereas porous and molecularly rough interfaces of open carbon nanotube membranes are found to glide with little friction, a comparably smooth interface of end-capped nanotubes is effectively stuck. The addition of salt to the water layer is found to reduce the sliding friction. Surprisingly, the intervening layers of water remain fluid in all cases, even in the case of high apparent friction between the two membranes.
Reference
Kalra A, Garde S and Hummer G (). "Lubrication by molecularly thin water films confined between nanostructured membranes
," Euro. Phys. J. - Special Topics, 189, 147-154
Bibtex
@article{kalra2010lubrication, title = {Lubrication by molecularly thin water films confined between nanostructured membranes}, author = {Kalra, A and Garde, S and Hummer, G}, journal = {The European Physical Journal Special Topics}, volume = {189}, number = {1}, pages = {147--154}, year = {2010}, doi = {10.1140/epjst/e2010-01317-9}