Hydration lubrication of polyzwitterionic brushes leads to nearly friction- and adhesion-free droplet motion

Daniel, Daniel; Chia, Alfred Yu Ting; Moh, Lionel C. H.; Liu, Rongrong; Koh, Xue Qi; Zhang, Xing; Tomczak, Nikodem

doi:10.1038/s42005-019-0205-x

Cited by 51 publications

(103 citation statements)

References 43 publications

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“…underwater superleophobic surface). Droplet probe AFM technique described here will greatly complement other ultra-sensitive surface wetting characterization tools previously reported, such as the droplet force apparatus [16,17] and the scanning droplet adhesion microscope [11]. However unlike previous approaches, our approach does not require any specialized instrument beyond a conventional AFM setup, which are available to many research groups.…”

Section: Discussionmentioning

confidence: 96%

“…The most common approach is to use a cantilever force sensor to directly measure the friction and adhesion forces (with a typical 0.1 µN resolution) acting on a millimetric droplet [14][15][16]. Recently, by greatly suppressing the environmental noise, our group has improved the resolution of such an instrument (which we named the Droplet Force Apparatus) to * daniel@imre.a-star.edu.sg about 5 nN [17]. More impressively, by combining a sensitive force sensor with a motorized sample stage, Ras and co-workers were not only able to achieve a similar nN force resolution, but were also able to map wetting variations with a lateral resolution of 10 µm [11].…”

Section: Introductionmentioning

confidence: 99%

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Mapping micrometer-scale wetting properties of superhydrophobic surfaces

Daniel

Lay

Sng

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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There is a huge interest in developing super-repellent surfaces for anti-fouling and heat-transfer applications. To characterize the wetting properties of such surfaces, the most common approach is to place a millimetric-sized droplet and measure its contact angles. The adhesion and friction forces can then be inferred indirectly using the Furmidge's relation. While easy to implement, contact angle measurements are semi-quantitative and cannot resolve wetting variations on a surface. Here, we attach a micrometric-sized droplet to an Atomic Force Microscope cantilever to directly measure adhesion and friction forces with nanonewton force resolutions. We spatially map the micron-scale wetting properties of superhydrophobic surfaces and observe the time-resolved pinning-depinning dynamics as a droplet detaches from or moves across the surface.

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Section: Discussionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

Mapping micrometer-scale wetting properties of superhydrophobic surfaces

Daniel

Lay

Sng

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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“…The friction of our etched silicon samples spans a very wide force range due to their topographical differences, where the most sparse spikes of sample A allow for an ultralow dimensionless friction force F μ =γD ¼ 4 ± 3 ð ÞÁ10 À4 that overcomes the friction of previously studied superhydrophobic surfaces made of micropillars 9,45 , SOCAL 9 , and silicone nanofilaments 19 , as well as lubricated surfaces 9 and a "nearly friction-and adhesion-free" underwater-SOCAL surface 20 (Fig. 4).…”

Section: Resultsmentioning

confidence: 99%

“…The tilt-stage 4,5,15,16 and oscillating droplet tribometer 17 techniques have been developed to measure droplet friction forces. One further, especially important emerging technique is the use of force-calibrated elastic cantilevers (spring constant k p ) to measure the friction force of droplets moving on various substrates [7][8][9][18][19][20] , including moderately superhydrophobic 7,9,19 , SOCAL 9,20 , and lubricated 8,9 coatings. The force is directly obtained through optical detection of the deflection (Δx) of the cantilever: F ¼ Àk p Δx.…”

mentioning

confidence: 99%

“…The force is directly obtained through optical detection of the deflection (Δx) of the cantilever: F ¼ Àk p Δx. Various kinds of cantilevers have been used to study liquid-repellent surfaces, including thick rectangular glass capillaries (side lengths 0:04 À 0:4 mm, k p ¼ 100 À 200 nN μm −1 , force resolution~40 nN) 7,19 and thick polymeric tubes (inner/ outer radii 0:29=0:36 mm, k p ¼ 2 À 30 nN μm −1 , force resolution $ 10 À 100 nN) 8,9,20 . The main downside of those cantilevers is that their width is comparable to the droplet size, which affects the droplet shape and disturbs the flow inside the droplet.…”

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confidence: 99%

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Water droplet friction and rolling dynamics on superhydrophobic surfaces

et al. 2020

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Superhydrophobicity is a remarkable surface property found in nature and mimicked in many engineering applications, including anti-wetting, anti-fogging, and anti-fouling coatings. As synthetic superhydrophobic coatings approach the extreme non-wetting limit, quantification of their slipperiness becomes increasingly challenging: although contact angle goniometry remains widely used as the gold standard method, it has proven insufficient. Here, micropipette force sensors are used to directly measure the friction force of water droplets moving on super-slippery superhydrophobic surfaces that cannot be quantified with contact angle goniometry. Superhydrophobic etched silicon surfaces with tunable slipperiness are investigated as model samples. Micropipette force sensors render up to three orders of magnitude better force sensitivity than using the indirect contact angle goniometry approach. We directly measure a friction force as low as 7 ± 4 nN for a millimetric water droplet moving on the most slippery surface. Finally, we combine micropipette force sensors with particle image velocimetry and reveal purely rolling water droplets on superhydrophobic surfaces.

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Double‐Defense Design of Super‐Anti‐Fouling Membranes for Oil/Water Emulsion Separation

Dong

Zhu

Fang

et al. 2022

Adv Funct Materials

194

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Oil fouling threatens the water flux stability of membranes for oil/water separation. Simple hydrophilic modification fights for an opportunity to prevent oil contamination but fails to eliminate severe water flux decline. In essence, a “single‐defense” mechanism is insufficient to build a potent barrier against accumulated cake layer under a filtration environment. This work reports a “double‐defense” design by integrating hydrophilic polymer brushes and hydrogel layer on oil/water separation membranes for desired anti‐oil‐fouling property, where a poly(vinylidene fluoride) porous membrane is first covered by a layer of poly(hydroxyethyl methylacrylate) hydrogel and then controllably grafted with poly(sulfobetaine) brushes. The spatially hierarchical structure establishes a highly covered “double‐defense” barrier for the membrane surface to efficiently repel oil adhesion and the formation of an accumulated cake layer. When separating various surfactant‐stabilized oil‐in‐water emulsions, the permeating flux displays a nearly zero decline throughout the whole filtration period. Most importantly, the permeating flux of the membrane is almost the same when filtrating pure water and filtrating oil‐in‐water emulsions, which is difficult to be achieved by the general membranes, indicating that the membrane has excellent anti‐oil‐fouling property superior to the currently reported membranes.

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Hydration lubrication of polyzwitterionic brushes leads to nearly friction- and adhesion-free droplet motion

Cited by 51 publications

References 43 publications

Mapping micrometer-scale wetting properties of superhydrophobic surfaces

Mapping micrometer-scale wetting properties of superhydrophobic surfaces

Water droplet friction and rolling dynamics on superhydrophobic surfaces

Double‐Defense Design of Super‐Anti‐Fouling Membranes for Oil/Water Emulsion Separation

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