Ultrafast Oleophobic–Hydrophilic Switching Surfaces for Antifogging, Self-Cleaning, and Oil–Water Separation

Brown, Philip S.; Atkinson, O. D. L. A.; Badyal, J. P. S.

doi:10.1021/am500882y

Cited by 151 publications

(125 citation statements)

References 67 publications

(142 reference statements)

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“…Surprisingly, it is also possible to have oil contact angles higher than water contact angles using urea linkers (NHCONH), which is rare in the literature. [27][28][29][30][31][32][33][34][35] In all the examples reported in the literature, there is the presence of both highly oleophobic parts such as fl uorinated materials and highly hydrophilic parts such as charged or highly polar species. For example, the group of Zhang reported the preparation of superhydrophilic/superoleophobic (in air) by mixing poly(diallyldimethylammonium chloride) (PDDA) with sodium perfl uorooctanoate (PFO).…”

Section: Surface Hydrophobicity and Oleophobicitymentioning

confidence: 99%

“…Here, we show also that some of these monomers can lead to both hydrophilic and oleophobic properties. This unusual surface property is rare in the literature [27][28][29][30][31][32][33][34][35] but possible by combining hydrophilic and oleophobic materials, and can found other applications in oil/water separation, [36][37][38] for example.…”

Section: Introductionmentioning

confidence: 99%

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Highly Polar Linkers (Urea, Carbamate, Thiocarbamate) for Superoleophobic/Superhydrophobic or Oleophobic/Hydrophilic Properties

Darmanin

Guittard

2015

Adv Materials Inter

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Due to the much lower surface tension of oils in comparison to water, it is extremely difficult to obtain superoleophobic properties and also both oleophobic and hydrophilic properties. While the obtaining of superoleophobic properties needs extremely complex surface structures such as reentrant structures to impede the oil wetting, the obtaining of both oleophobic and hydrophilic properties needs the use of both oleophobic materials (fluorinated materials) and hydrophilic materials (charged or polar species). Here, by electropolymerization of original 3,4‐ethylenedioxythiophene derivatives containing both fluorinated chains (C8F17, C6F13, or C4F9) and highly polar linkers (thiocarbamate SCONH, carbamate OCONH, and urea NHCONH), the possibility to obtain superoleophobic properties and also both oleophobic and hydrophilic properties is reported for the first time. More precisely superoleophobic properties are obtained with different fluorinated chain lengths and linkers while the obtaining of both oleophobic and hydrophilic properties is possible only with the most polar urea NHCONH linkers.

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Section: Surface Hydrophobicity and Oleophobicitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Highly Polar Linkers (Urea, Carbamate, Thiocarbamate) for Superoleophobic/Superhydrophobic or Oleophobic/Hydrophilic Properties

Darmanin

Guittard

2015

Adv Materials Inter

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“…The underwater oleophobicity is to be distinguished from the in-air oleophobicity which stands for resistance to oil adhesion in air. Inspired by biological surfaces such as sharkskin and clamshells that are resistant to biological or organic adhesion underwater, the materials science community has developed a plethora of interfacial materials with underwater superoleophobicity for different applications such as marine biofouling control [21,22] and oil-water separations [23][24][25][26][27][28][29][30][31][32][33]. In general, there are two requirements for constructing an underwater superoleophobic surface: rough (textured) surface morphology and hydrophilic surface chemistry.…”

Section: Introductionmentioning

confidence: 99%

Tailoring surface charge and wetting property for robust oil-fouling mitigation in membrane distillation

Wang

Jin

Hou

et al. 2016

Journal of Membrane Science

128

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a b s t r a c tThe efforts of developing anti-oil-fouling membranes have so far been focusing on tailoring membrane surface wetting properties, whereas the impacts of surface charge are often eclipsed. In this study, we investigated the impacts of surface charge and wetting property on oil fouling kinetics in membrane distillation (MD). Two composite membranes with in-air hydrophilic and underwater oleophobic surfaces, one of positive charge and the other of negative charge, were fabricated by modifying a hydrophobic polyvinylidene fluoride (PVDF) membrane with hydrophilic polyelectrolytes with different charges. The modified composite membranes were compared with the reference PVDF membrane for their contact angles, adhesion force curves, and fouling kinetics in MD processes. It was found that the negatively charged composite membrane performed the best in mitigating fouling by the negatively charged oil emulsion, followed by the positively charged composite membrane, with the pristine PVDF membrane being the most susceptible to oil fouling in MD experiments. The results from underwater oil CA measurements and oil probe force spectroscopy corroborated the results in the fouling experiments. The impact of surface charges on oil-membrane interaction and associated mechanism were also discussed.

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“…However, it is possible to create a coating that repels oils but attracts water. [58][59][60][61][62][63] This can be achieved through the use of a fluorosurfactant, which contains a high surface energy head group and a low surface energy tail group. Fluorosurfactants are typically used as additives in paints or cleaners, however, the presence of the ionic head group common in many examples allows for them to become complexed, either in solution or on a coating, with electrolyte-containing polymers.…”

Section: (D)mentioning

confidence: 99%

Designing bioinspired superoleophobic surfaces

Brown

Bhushan

2015

APL Materials

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Nature provides a range of functional surfaces, for example, water-repellent or superhydrophobic surfaces, most common among them the lotus leaf. While water-repellency is widespread in nature, oil-repellency is typically limited to surfaces submerged in water, such as fish scales. To achieve oleophobicity in air, inspiration must be taken from natural structures and chemistries that are not readily available in nature need to be introduced. Researchers usually turn to fluorinated materials to provide the low surface energy that, when combined with bioinspired surface topography, is the key to unlocking oil-repellency. This review presents the state-of-the-art in the fabrication of superoleophobic surfaces.

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Ultrafast Oleophobic–Hydrophilic Switching Surfaces for Antifogging, Self-Cleaning, and Oil–Water Separation

Cited by 151 publications

References 67 publications

Highly Polar Linkers (Urea, Carbamate, Thiocarbamate) for Superoleophobic/Superhydrophobic or Oleophobic/Hydrophilic Properties

Highly Polar Linkers (Urea, Carbamate, Thiocarbamate) for Superoleophobic/Superhydrophobic or Oleophobic/Hydrophilic Properties

Tailoring surface charge and wetting property for robust oil-fouling mitigation in membrane distillation

Designing bioinspired superoleophobic surfaces

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