Surface charge-induced EDL interaction on the contact angle of surface nanobubbles

Jing, Dalei; Li, Dayong; Pan, Yunlu; Bhushan, Bharat

doi:10.1021/acs.langmuir.6b00976

Cited by 11 publications

(9 citation statements)

References 47 publications

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“…This is especially true for surface nanobubbles, which are the main gas state. They have attracted intense research interest because of their peculiar features and potential applications in many fields. − Up to now, the characteristics, − formation methods, − influence factors ,− and some potential applications − of surface nanobubbles have been investigated. However, a comprehensive understanding of the anomalous large contact angle (in this paper, contact angle means water side contact angle) and longevity (stability) of nanobubbles is still an open question.…”

Section: Introductionmentioning

confidence: 99%

Study on Nanobubble-on-Pancake Objects Forming at Polystyrene/Water Interface

Pan

Zhao

et al. 2016

Langmuir

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Surface nanobubbles, which are the main gaseous state forming at the solid/liquid interface, have received extensive attention due to their peculiar features and potential applications. Nano/micro pancakes and interfacial gas enrichment (IGE) are observed at the water-solid interface, which suggest nanobubbles may coexist with IGE. An intuitive case for the coexistence of nanobubbles and IGE is the nanobubble-on-pancake-like objects. However, it still is not clear whether nanobubbles sit on top of an IGE or the IGE surrounds a nanobubble, which increasingly is seen to be important for understanding the stability and small contact angle of nanobubbles. In this study, the nanobubble-on-pancake-like objects were investigated on a polystyrene (PS) surface. Considering the nanobubble-like objects forming on PS film might be blisters formed because of osmosis, whether such objects are gaseous state or blisters therefore was investigated first. Then, the structure of the nanobubble-on-pancake-like object was analyzed, on the basis of which the stability of nanobubbles under tip perturbation was discussed. The pancake-like domains of the bubble-on-pancake composite disappeared, but the bubble part remained. This indicates that nanobubbles do not sit on top of the pancakes, but are pinned on the solid surface. This is in good agreement with the contact line pinning theory, and is helpful to understanding the abnormal long lifetime (stability) of nanobubbles.

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Section: Introductionmentioning

confidence: 99%

Study on Nanobubble-on-Pancake Objects Forming at Polystyrene/Water Interface

Pan

Zhao

et al. 2016

Langmuir

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“…As known, the OH – species in water tends to be adsorbed at the gas–water interface, leading to the negative charging at the interface of bubbles . In response to the charge interaction, the Laplace pressure would be amended. − However, such an effect might be insignificant to impact the evolution dynamics of the bubbles with large sizes shown in this work, because the ζ potential is only ∼30 mV . Upon the e-beam excitation, the PVAC shell (polymer) would be positively charged with the potential, which is much larger than the ζ potential .…”

mentioning

confidence: 84%

Versatile Printing of Substantial Liquid Cells for Efficiently Imaging In Situ Liquid-Phase Dynamics

Liu

Cao

et al. 2021

Nano Lett.

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Through its ability to image liquid-phase dynamics at nano/atomic-scale resolution, liquid-cell electron microscopy is essential for a wide range of applications, including wet-chemical synthesis, catalysis, and nanoparticle tracking, for which involved structural features are critical. However, statistical investigations by usual techniques remain challenging because of the difficulty in fabricating substantial liquid cells with appreciable efficiency. Here, we report a general approach for efficiently printing huge numbers of ready-to-use liquid cells (∼9000) within 30 s by electrospinning, with the unique feature of statistical liquid-phase studies requiring only one experimental time slot. Our solution efficiently resolves a complete transition picture of bubble evolution and also the induced nanoparticle motion. We statistically quantify the effect of the electron dose rate on the bubble variation and conclude that the bubble-driven nanoparticle motion is a ballistic-like behavior insignificant to morphological asymmetries. The versatile approach here is critical for statistical research, offering great opportunities in liquid-phase-associated dynamic studies.

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“…Surface nanobubbles have attracted considerable concern over the past two decades because of their potential applications. − The abnormal longevity − and small contact angle − are two remarkable properties of surface nanobubbles related to the force that pins them onto the solid/liquid interface. The pinning force was thought to prevent the triple-phase contact line from moving and thus led to the difference in contact angles of surface bubbles on the macro- and nanoscale .…”

Section: Introductionmentioning

confidence: 99%

Manipulating Trapped Nanobubbles Moving and Coalescing with Surface Nanobubbles

et al. 2022

Langmuir

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Trapped nanobubbles are observed nucleating at nanopits on a pitted substrate, while surface nanobubbles are usually formed on the smooth solid surface in water. In this work, trapped nanobubbles and surface nanobubbles were captured by a tapping-mode atomic force microscope (AFM) on a nanopitted substrate based on the temperature difference method. A single trapped nanobubble was manipulated to change into a surface nanobubble, then to change into the trapped nanobubble again. At the same time, surface nanobubbles can be moved to merge into a trapped nanobubble. Our results show that the scan load and the size of the scan area were the main factors that significantly affect the mobility of surface/trapped nanobubbles. The coalescence and mutual transformation of the two kinds of nanobubbles indicate that trapped nanobubbles and surface nanobubbles have the same chemical nature, which also provides vital experimental proof of the existence of nanobubbles in the course of contact line depinning. Our results are of great significance for understanding nanobubble stability and providing guidelines in some industrial applications.

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Surface charge-induced EDL interaction on the contact angle of surface nanobubbles

Cited by 11 publications

References 47 publications

Study on Nanobubble-on-Pancake Objects Forming at Polystyrene/Water Interface

Study on Nanobubble-on-Pancake Objects Forming at Polystyrene/Water Interface

Versatile Printing of Substantial Liquid Cells for Efficiently Imaging In Situ Liquid-Phase Dynamics

Manipulating Trapped Nanobubbles Moving and Coalescing with Surface Nanobubbles

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