Increased Stability and Size of a Bubble on a Superhydrophobic Surface

Ling, William Yeong Liang; Lu, Gabriel; Ng, Tuck Wah

doi:10.1021/la104982p

Cited by 40 publications

(47 citation statements)

References 17 publications

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“…Air pockets captured in the nanostructure of the lotus leaf could easily coalesce with the air bubble, and the microstructure could provide enough space to form gas bridges for air-bubble spreading. [24] In fact, several insects hiding or hunting underwater exploit the property of superaerophilicity. [25][26][27][28][29] Water spiders…”

Section: Doi: 101002/adma201703053mentioning

confidence: 99%

“…Thus, air is retained in their nano/microstructures. [24,35,36] Here, CAH is defined as the difference between the cosine of the maximum and minimum static contact angles on the uphill (θ max ) and downhill (θ min ) sides upon tilting the substrate at a particular angle. As gas bubbles come into contact with these superhydrophobic interfaces, air pockets captured in the microstructure could easily coalesce with the air bubbles and then lead to air-bubble spreading.…”

Section: Theoretical Investigation For Gas-bubble Superwettability Inmentioning

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: Doi: 101002/adma201703053mentioning

confidence: 99%

Section: Theoretical Investigation For Gas-bubble Superwettability Inmentioning

confidence: 99%

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

et al. 2017

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“…When immersed in water, SH surfaces have been shown to develop a stable thin film of air called a plastron [22,23]. Plastrons are also believed to be responsible for the ability of sessile bubbles to exist on the SH surfaces at volumes much larger than anticipated [24]. On non-SH PTFE, it is conceivable that regions of non-visible surface air entrapment may continue to exist even when the larger bubbles dissipate through diffusion [17].…”

Section: Resultsmentioning

confidence: 99%

Glycerol–water sessile drop elongation on PTFE inclines in relation to biochemical applications

Zahidi

Cheong

Huynh

et al. 2015

Colloids and Surfaces A: Physicochemical and Engineering Aspect

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“…The derivation of bubble contact angle (θ b ) from Young's equation is possible by interchanging solid–liquid (γ sl ) and solid–vapor (γ sv ) surface tensions, followed by applying trigonometric relations. It is apparent from Equation that θ w and θ b are complementary to each other

θ_{normalb} = 180 ° - θ_{normalw}

…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Recent Progress in Fabricating Superaerophobic and Superaerophilic Surfaces

George

Chidangil

George

2017

Adv Materials Inter

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In spite of large amount of research in fabricating surfaces of varying wettability by biomimicking the naturally occurring surfaces, the work on fundamentally and industrially important air bubble adhesion on solid surfaces and its applications are still in the burgeoning stage. The present progress report provides a discussion and a critical evaluation of the recent literature available on the fabrication of superaerophilic/superaerophobic surfaces via synergic modification of surface topography and surface chemistry. An abridge on the physics behind bubble wetting on a solid in a liquid medium is deciphered here, considering the interfacial surface tension balance at the three‐phase contact line, Laplace pressure, hydrostatic pressure, and surface forces, respectively. Emphasis is made on the advancement in micro/nanofabrication technologies to fabricate surfaces that break the conventional wisdom of complementary behavior of water and air bubble contact angles. The progress report presented here also shines light on the mechanism of air bubble dynamics on solid surfaces and the latest developments in achieving surfaces of varied air bubble adhesion and its applications. Finally, the prospects of the superaerophobic and superaerophilic surfaces in the near future together with the challenges faced in accomplishing them are also insinuated.

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Increased Stability and Size of a Bubble on a Superhydrophobic Surface

Cited by 40 publications

References 17 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

Glycerol–water sessile drop elongation on PTFE inclines in relation to biochemical applications

Recent Progress in Fabricating Superaerophobic and Superaerophilic Surfaces

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