Droplet slipperiness despite surface heterogeneity at molecular scale

S Lepikko and YM Jaques and M Junaid and M Backholm and J Lahtinen and J Julin and V Jokinen and T Sajavaara and M Sammalkorpi and AS Foster and RHA Ras, NATURE CHEMISTRY (2023).

DOI: 10.1038/s41557-023-01346-3

Friction determines whether liquid droplets slide off a solid surface or stick to it. Surface heterogeneity is generally acknowledged as the major cause of increased contact angle hysteresis and contact line friction of droplets. Here we challenge this long-standing premise for chemical heterogeneity at the molecular length scale. By tuning the coverage of self-assembled monolayers (SAMs), water contact angles change gradually from about 10 degrees to 110 degrees yet contact angle hysteresis and contact line friction are low for the low-coverage hydrophilic SAMs as well as high-coverage hydrophobic SAMs. Their slipperiness is not expected based on the substantial chemical heterogeneity of the SAMs featuring uncoated areas of the substrate well beyond the size of a water molecule as probed by metal reactants. According to molecular dynamics simulations, the low friction of both low- and high-coverage SAMs originates from the mobility of interfacial water molecules. These findings reveal a yet unknown and counterintuitive mechanism for slipperiness, opening new avenues for enhancing the mobility of droplets. Surface heterogeneity is generally acknowledged as the major cause of liquid-solid friction, affecting whether droplets slide off the surface or stick to it. Now, a model surface of self-assembled monolayers has been used to investigate how molecular-scale surface heterogeneity affects water contact angle hysteresis and contact line friction. The high-coverage hydrophobic surface is slippery, as-counter-intuitively-is the low-coverage hydrophilic surface.

Return to Publications page