Long‐Range Hydrophilic Attraction between Water and Polyelectrolyte Surfaces in Oil

Shi, Chen; Yan, Bin; Xie, Lei; Zhang, Ling; Wang, Jingyi; Takahara, Atsushi; Zeng, Hongbo

doi:10.1002/anie.201608219

Cited by 112 publications

(95 citation statements)

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“…Despite recent progress, there is little direct experimental evidence for the presence of the water film between the oil droplet and the substrate, and most previous discussions implicitly assume the presence of such a hydration layer. [7,8,11,12]. The thickness of this water film-should it exist-is not known and its relation to oil-repellency remains poorly understood.…”

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confidence: 99%

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

et al. 2019

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Recently, there has been much progress in the design and application of oil-repellent superoleophobic surfaces. Polyzwitterionic brush surfaces are of particular interest, because of their ability to repel oil under water, even in the absence of micro-/nano-structures. The origin of this underwater superoleophobicity is attributed to the presence of a stable water film beneath the oil droplet, but this had not been demonstrated experimentally. Here, using optical interferometric techniques, we show that an oil droplet effectively hydroplanes over a water film, whose thickness is between one hundred and hundreds of nanometres. In addition, using a custom-built Droplet Force Apparatus, we measured the friction and adhesion forces to be in the nN range for millimetric-sized droplets. These forces are much lower than for other classes of well-known liquid-repellent surfaces, including the lotus-leaf effect and lubricant-infused surfaces, where the typical force is on the order of µN. arXiv:1906.09910v2 [cond-mat.soft]

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confidence: 99%

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

et al. 2019

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“…[ 18–24 ] The zwitterionic polymers carry functional groups like carboxybetaine, sulfobetaine, phosphobetaine, etc., which have both positive and negative charge in the same monomer. [ 25 ] The strong polarity gives rise to a hydration layer around the zwitterionic polymer chains, [ 26,27 ] which can prevent the adsorption of oil droplets onto the polymer surfaces. [ 28 ] Studies have reported that copolymer hydrogels prepared by poly(ethylene glycol)diacrylate (PEGDA) and zwitterionic monomer, such as carboxybetaine methacrylate and sulfobetaine methacrylate (SBMA), demonstrate better hydrophilicity than those of PEGDA.…”

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confidence: 99%

Zwitterionic Polymer‐Grafted Superhydrophilic and Superoleophobic Silk Fabrics for Anti‐Oil Applications

Cheng

Wang

et al. 2020

Macromol. Rapid Commun.

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A highly anti‐oil fabric membrane is synthesized by surface grafting of zwitterionic poly(sulfobetaine methacrylate) (PSBMA) onto the fabric surface. The fabric membrane is first enzymatically modified to create more reactive amine groups on the surface. A surface‐initiated atom transfer radical polymerization (SI‐ATRP) reaction is then performed to modify the fabric membrane surface with a dense PSBMA brush layer. Surface characterization indicates that the brush‐grafted fabric membrane exhibits increased surface roughness and improved superhydrophilicity. The PSBMA‐modified silk fabrics show a very large contact angle for oil droplets in water, and have excellent oil resistance in air and in water–oil mixtures.

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“…Recent interfacial force measurements have shown several interesting findings. Hayashi et al reported the presence of several nm-thick, repulsive layers near the bioinert oligoethylene glycol surfaces (Hayashi et al, 2012), and Shi et al demonstrated there is a long-range attraction between water and zwitterionic polymer brushes in oil (Shi et al, 2016). Further studies on the structures and dynamics of water in the vicinity of polymer/water interface potentially enable to overcome the commonly taken trial-and-error approaches toward the rational design, or even the prediction of new bioinert materials.…”

Section: Toward Rational Design Of New Materials: Bioinertnessmentioning

confidence: 99%

Interplays of Interfacial Forces Modulate Structure and Function of Soft and Biological Matters in Aquatic Environments

Tanaka

2020

Front. Chem.

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Water had been considered as a passive matrix that merely fills up the space, supporting the diffusion of solute molecules. In the past several decades, a number of studies have demonstrated that water play vital roles in regulating structural orders of biological systems over several orders of magnitude. Water molecules take versatile structures, many of which are transient. Water molecules act as hydrogen bond donors as well as acceptors and biochemical reactions utilize water molecules as nucleophiles. Needless to say, the same principle holds for the synthetic materials that function under water: the conformation, dynamics and functions of molecules are significantly influenced by the surrounding water. This review sheds light on how the structure and function of soft and biological matter in aquatic environments are modulated by the orchestration of various interfacial forces.

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Long‐Range Hydrophilic Attraction between Water and Polyelectrolyte Surfaces in Oil

Cited by 112 publications

References 50 publications

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

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

Zwitterionic Polymer‐Grafted Superhydrophilic and Superoleophobic Silk Fabrics for Anti‐Oil Applications

Interplays of Interfacial Forces Modulate Structure and Function of Soft and Biological Matters in Aquatic Environments

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