The <i>Salvinia</i> Paradox: Superhydrophobic Surfaces with Hydrophilic Pins for Air Retention Under Water

Barthlott, Wilhelm; Schimmel, Thomas; Wiersch, Sabine; Koch, Kerstin; Brede, M.; Barczewski, M.; Walheim, Stefan; Weis, Aaron; Kaltenmaier, Anke; Leder, Alfred; Bohn, Holger Florian

doi:10.1002/adma.200904411

Cited by 450 publications

(501 citation statements)

References 30 publications

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“…Reproduced with permission. [30] Copyright 2010, Wiley-VCH. e) The steady pinning effect of air bubbles (i.e., aerophobicity and high adhesion property) on a rose petal interface with a combination of micropapillae and nanofolds.…”

Section: Reliable Manipulation Of Gas Bubbles By Regulating Interfacimentioning

confidence: 99%

“…The patches (with high interface energy) at the tips of the hairs presumably stabilize the air film against pressure fluctuations (Figure 1d). [30] The steady pinning effect of air bubbles with a final spherical shape is observed on a rose petal, i.e., aerophobicity. This novel phenomenon is attributed to the micro/nanohierarchical rough structures (microscaled papillae and nanofolds).…”

Section: Introductionmentioning

confidence: 99%

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Superwettability of Gas Bubbles and Its Application: From Bioinspiration to Advanced Materials

et al. 2017

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Gas bubbles in aqueous media are common and inevitable in, for example, agriculture and industrial processes. The behaviors of gas bubbles on solid interfaces, including generation, growth, coalescence, release, transport, and collection, are crucial to gas‐bubble‐related applications, which are always determined by gas‐bubble wettability on solid interfaces. Here, the recent progress regarding the study of interfaces with gas‐bubble superwettability in aqueous media, i.e., superaerophilicity and superaerophobicity, is summarized. Some examples illustrate how to design microstructures and chemical compositions to achieve reliable and effective manipulation of gas‐bubble wettability on artificial interfaces. These designed interfaces exhibit excellent performance in gas‐evolution reactions, gas‐adsorption reactions, and directional gas‐bubble transportation. Moreover, progress in the theoretical investigation of gas‐bubble superwettability is reported. Lastly, some challenges are presented, such as the reliable manipulation of gas‐bubble wettability and the establishment of mature theory for exactly and systematically explaining gas‐bubble wetting phenomena.

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Section: Reliable Manipulation Of Gas Bubbles By Regulating Interfacimentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Superwettability of Gas Bubbles and Its Application: From Bioinspiration to Advanced Materials

et al. 2017

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“…[ 1 ] Moving toward submerged applications requires a new inspiration: a promising candidate is the Salvinia molesta (Figure 1 a), because of its superior gas trapping capabilities. [ 6,[18][19][20] The gas entrapped within surface asperities can be either air or the vapor phase coexisting with the liquid: albeit the partial pressure of the other gases stabilizes the Cassie state, their presence is not a requirement for (meta)stable superhydrophobicity [ 21 ] (see the Supporting Information for additional details on the role of dissolved gases). The entrapped gas may be lost through different mechanisms, analyzed in detail below, determining the failure of superhydrophobicity:…”

Section: Doi: 101002/admi201500248mentioning

confidence: 99%

Unraveling the Salvinia Paradox: Design Principles for Submerged Superhydrophobicity

Amabili

Giacomello

Meloni

et al. 2015

Adv Materials Inter

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“…In a type of water weed hydrophilic patches at the tips of the REVIEW structures add to this effect. 92 The flexibility of the hairs absorbs any pulses of pressure preventing loss of gas from the features of the surface, particularly when the tops of the hairs are hydrophilic. 86 This reduces the tendency for the gas film to lose volume and eventually collapse.…”

Section: Maintaining An Air Layer Underwater (Plastrons)mentioning

confidence: 99%

The superhydrophobicity of polymer surfaces: Recent developments

Shirtcliffe

McHale

Newton

2011

J Polym Sci B Polym Phys

161

108

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Superhydrophobicity is the extreme water repellence of highly textured surfaces. The field of superhydrophobicity research has reached a stage where huge numbers of candidate treatments have been proposed and jumps have been made in theoretically describing them. There now seems to be a move to more practical concerns and to considering the demands of individual applications instead of more general cases. With these developments, polymeric surfaces with their huge variety of properties have come to the fore and are fast becoming the material of choice for designing, developing, and producing superhydrophobic surfaces.

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The Salvinia Paradox: Superhydrophobic Surfaces with Hydrophilic Pins for Air Retention Under Water

Cited by 450 publications

References 30 publications

Superwettability of Gas Bubbles and Its Application: From Bioinspiration to Advanced Materials

Superwettability of Gas Bubbles and Its Application: From Bioinspiration to Advanced Materials

Unraveling the Salvinia Paradox: Design Principles for Submerged Superhydrophobicity

The superhydrophobicity of polymer surfaces: Recent developments

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