To the editor
Deng et al. recently reported1 that the friction force between the tip of an atomic force microscope and a graphite surface increases with decreasing load. This phenomenon — which is described as a curve with a negative slope when the friction force is plotted against load, and thus leads to a so-called negative friction coefficient — was explained by a model where the adhesion between the atomic force microscope tip and the graphite surface is stronger than the dispersion forces holding the layers in graphite together1. Here, by way of two examples of the friction between polymer-coated surfaces in aqueous solution, I illustrate that such a situation is not limited to graphite or similarly structured materials, yet is a more general phenomenon related to hysteresis in the adhesive interaction between two sliding bodies.
The first example refers to the friction between layers of methylcellulose2 anchored by hydrophobic interactions to a hydrophobized silica surface and a hydrophobized silica microparticle. Figure 1a shows the corresponding friction force-versus-load curve. As a load is applied, the friction force increases linearly with the load, with a change in the friction coefficient at approximately 5 nN. It is likely that the change in the frictional response results from an irreversible reorganization of the polymer layer arising from the combination of high load and shear stress. As unloading starts at about 8 nN, the friction force continues to increase as load decreases. This may occur because the adhesion between the polymer films is stronger than the force anchoring the polymers to the substrate, thus allowing the polymer layer to be lifted as the load decreases. This explanation is similar to the one given by Deng et al. for the case of graphite1, although the two systems are fundamentally different (further details are given in the Supplementary Information).
The second example involves the interaction between silica surfaces coated with a hydrophobic, cationic diblock copolymer3,4 by means of electrostatic anchoring. Figure 1b shows that, after an initial jump to high friction resulting from adhesive contact, an almost linear increase in the friction force develops with increasing load. As the load is reduced, however, the friction force first increases and then levels off until the surfaces pull free from each other. In this case, a negative friction coefficient appears because the intermolecular interactions between the hydrophobic blocks are stronger than the forces between the cationic blocks and the silica surface. In fact, as unloading continues, the bridging polymers start to snap off, and the friction force declines. This process is almost reversible, both within loading–unloading cycles and between them.
References
Deng, Z., Smolyanitsky, A., Qunyang, L., Feng, X-Q. & Cannara, R. J. Nature Mater. 11, 1032–1037 (2012).
Bodvik, R., Thormann, E., Karlson, L. & Claesson, P. M. Phys. Chem. Chem. Phys. 13, 4260–4268 (2011).
Loan, T. T. et al. J. Colloid Interface Sci. 342, 142–146 (2010).
Dedinaite, A. et al. Soft Matter 6, 2489–2498 (2010).
Pettersson, T., Naderi, A., Makuska, R. & Claesson, P. M. Langmuir 24, 3336–3347 (2008).
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Thormann, E. Negative friction coefficients. Nature Mater 12, 468 (2013). https://doi.org/10.1038/nmat3656
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DOI: https://doi.org/10.1038/nmat3656
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