# The Influence of Surface Topography and Surface Chemistry on the   Anti-Adhesive Performance of Nanoporous Monoliths

**Authors:** Anna Eichler-Volf, Longjian Xue, Gregor Dornberg, He Chen, Alexander, Kovalev, Dirk Enke, Yong Wang, Elena V. Gorb, Stanislav N. Gorb, Martin, Steinhart

arXiv: 1703.07424 · 2017-03-23

## TL;DR

This study investigates how surface topography and chemistry influence the anti-adhesive properties of nanoporous monoliths, demonstrating that modifications in these features can significantly reduce adhesion forces and work of separation.

## Contribution

It introduces nanoporous monoliths with microspherical topographies and various surface chemistries, showing how these modifications affect adhesion and separation under different conditions.

## Key findings

- Microspherical topographies reduce adhesion by over tenfold.
- Liquid presence and surface chemistry significantly influence work of separation.
- Surface modifications enable tuning of anti-adhesive performance over an order of magnitude.

## Abstract

We designed spongy monoliths allowing liquid delivery to their surfaces through continuous nanopore systems (mean pore diameter ca. 40 nm). These nanoporous monoliths were flat or patterned with microspherical structures a few 10 microns in diameter, and their surfaces consisted of aprotic polymer or of TiO2 coatings. Liquid may reduce adhesion forces FAd; possible reasons include screening of solid-solid interactions and poroelastic effects. Softening-induced deformation of flat polymeric monoliths upon contact formation in the presence of liquids enhanced the work of separation WSe. On flat TiO2-coated monoliths, WSe was under wet conditions smaller than under dry conditions, possibly because of liquid-induced screening of solid-solid interactions. Under dry conditions, WSe is larger on flat TiO2-coated monoliths than on flat monoliths with polymeric surface. However, under wet conditions liquid-induced softening results in larger WSe on flat monoliths with polymeric surface than on flat monoliths with oxidic surface. Monolithic microsphere arrays show anti-adhesive properties; FAd and WSe are reduced by at least one order of magnitude as compared to flat nanoporous counterparts. On nanoporous monolithic microsphere arrays, capillarity (WSe is larger under wet than under dry conditions) and solid-solid interactions (WSe is larger on oxide than on polymer) dominate contact mechanics. Thus, the microsphere topography reduces the impact of softening-induced surface deformation and screening of solid-solid interactions associated with liquid supply. Overall, simple modifications of surface topography and chemistry combined with delivery of liquid to the contact interface allow adjusting WSe and FAd over at least one order of magnitude. (...)

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Source: https://tomesphere.com/paper/1703.07424