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Start date: 2000 × Has files: Yes × Type: Text × Publisher: Washington D.C. : American Chemical Society × Subject: adhesion × WGL Institute: INM ×

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    Monitoring the contact stress distribution of gecko-inspired adhesives using mechano-sensitive surface coatings
    (Washington D.C. : American Chemical Society, 2018) Neubauer, Jens W.; Xue, Longjian; Erath, Johann; Drotlef, Dirk-Michael; del Campo, Aránzazu; Fery, Andreas
    The contact geometry of microstructured adhesive surfaces is of high relevance for adhesion enhancement. Theoretical considerations indicate that the stress distribution in the contact zone is crucial for the detachment mechanism, but direct experimental evidence is missing so far. In this work, we propose a method that allows, for the first time, the detection of local stresses at the contact area of biomimetic adhesive microstructures during contact formation, compression and detachment. We use a mechano-sensitive polymeric layer, which turns mechanical stresses into changes of fluorescence intensity. The biomimetic surface is brought into contact with this layer in a well-defined fashion using a microcontact printer, while the contact area is monitored with fluorescence microscopy in situ. Thus, changes in stress distribution across the contact area during compression and pull-off can be visualized with a lateral resolution of 1 μm. We apply this method to study the enhanced adhesive performance of T-shaped micropillars, compared to flat punch microstructures. We find significant differences in the stress distribution of the both differing contact geometries during pull-off. In particular, we find direct evidence for the suppression of crack nucleation at the edge of T-shaped pillars, which confirms theoretical models for the superior adhesive properties of these structures.
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    Surface softening in metal-ceramic sliding contacts: An experimental and numerical investigation
    (Washington D.C. : American Chemical Society, 2015) Stoyanov, Pantcho; Merz, Rolf; Romero, Pedro A.; Wählisch, Felix C.; Torrents Abad, Oscar; Gralla, Robert; Stemmer, Priska; Kopnarski, Michael; Moseler, Michael; Bennewitz, Roland; Dienwiebel, Martin
    This study investigates the tribolayer properties at the interface of ceramic/metal (i.e., WC/W) sliding contacts using various experimental approaches and classical atomistic simulations. Experimentally, nanoindentation and micropillar compression tests, as well as adhesion mapping by means of atomic force microscopy, are used to evaluate the strength of tungsten?carbon tribolayers. To capture the influence of environmental conditions, a detailed chemical and structural analysis is performed on the worn surfaces by means of XPS mapping and depth profiling along with transmission electron microscopy of the debris particles. Experimentally, the results indicate a decrease in hardness and modulus of the worn surface compared to the unworn one. Atomistic simulations of nanoindentation on deformed and undeformed specimens are used to probe the strength of the WC tribolayer and despite the fact that the simulations do not include oxygen, the simulations correlate well with the experiments on deformed and undeformed surfaces, where the difference in behavior is attributed to the bonding and structural differences of amorphous and crystalline W-C. Adhesion mapping indicates a decrease in surface adhesion, which based on chemical analysis is attributed to surface passivation.