MICROFLOTATION OF FINE OIL DROPLETS BY SMALL AIR BUBBLES: EXPERIMENT AND THEORY

Hydrophobic oil droplets, particles and air bubbles can be dispersed in water as kinetically stabilized dispersions. It has been established since the 19th century that such objects harbor a negative electrostatic potential roughly twice larger than the thermal energy. The source of this charge continues to be one of the core observations in relation to hydrophobicity and its molecular explanation is still debated. What is clear though, is that the stabilizing interaction in these systems is understood in terms of electrostatic repulsion via DLVO theory. Recent work [Carpenter et al., PNAS 116 (2019) 9214] has added another element into the discussion, reporting the creation of bare near-zero charged droplets of oil in water that are stable for several days. Key to the creation of the droplets is a rigorous glassware cleaning procedure. Here, we investigate these conclusions and show that the cleaning procedure of glassware has no influence on the electrophoretic mobility of the droplets, that oil droplets with near-zero charge are unstable, and provide an alternative possible explanation for the observations involving glass surface chemistry.

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Multiple air-bubble enhanced oil rupture on nanostructured cellulose fabric for easy-oil cleaning fouled in a dry state

Scientific Reports ◽

10.1038/s41598-019-51216-7 ◽

2019 ◽

Vol 9 (1) ◽

Cited By ~ 1

Author(s):

Min-Sung Kim ◽

Tae-Jun Ko ◽

Seong Jin Kim ◽

Young-A. Lee ◽

Kyu Hwan Oh ◽

...

Keyword(s):

Aspect Ratio ◽

Solid Fraction ◽

High Aspect Ratio ◽

Air Bubbles ◽

Oil Droplets ◽

Water Contact ◽

Air Bubble ◽

Cellulose Fabric ◽

Oily Water ◽

Oil Fouling

Abstract Nanostructured cellulose fabric with an air-bubble-enhanced anti-oil fouling property is introduced for quick oil-cleaning by water even with the surface fouled by oil before water contact under a dry state. It is very challenging to recover the super-hydrophilicity because once the surface is oil-fouled, it is hard to be re-wetted by water. Anti-oil-fouling under a dry state was realized through two main features of the nanostructured, porous fabric: a low solid fraction with high-aspect-ratio nanostructures significantly increasing the retracting forces, and trapped multiscale air bubbles increasing the buoyancy and backpressure for an oil-layer rupture. The nanostructures were formed on cellulose-based rayon microfibers through selective etching with oxygen plasma, forming a nanoscale open-pore structure. Viscous crude oil fouled on a fabric under a dry state was cleaned by immersion into water owing to a higher water affinity of the rayon material and low solid fraction of the high-aspect-ratio nanostructures. Air bubbles trapped in dry porous fibers and nanostructures promote oil detachment from the fouled sites. The macroscale bubbles add buoyancy on top of the oil droplets, enhancing the oil receding at the oil-water-solid interface, whereas the relatively smaller microscale bubbles induce a backpressure underneath the oil droplets. The oil-proofing fabric was used for protecting underwater conductive sensors, allowing a robot fish to swim freely in oily water.

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Effect of morphology on interactions between nanoparticle-stabilised air bubbles and oil droplets

Soft Matter ◽

10.1039/c7sm02280h ◽

2018 ◽

Vol 14 (17) ◽

pp. 3246-3253 ◽

Cited By ~ 2

Author(s):

Victoria J. Cunningham ◽

Emma C. Giakoumatos ◽

Melissa Marks ◽

Steven P. Armes ◽

Erica J. Wanless

Keyword(s):

Air Bubbles ◽

Oil Droplets ◽

Oil Droplet ◽

Air Bubble ◽

Multiphase Systems

Adsorbed copolymer nanoparticle spheres and worms can stabilise oil droplet or air bubble pairs, or indeed multiphase systems.

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Probing Hydrophobic Interactions between Polymer Surfaces and Air Bubbles or Oil Droplets: Effects of Molecular Weight and Surfactants

Langmuir ◽

10.1021/acs.langmuir.1c02635 ◽

2021 ◽

Author(s):

Diling Yang ◽

Lei Xie ◽

Xiaohui Mao ◽

Lu Gong ◽

Xuwen Peng ◽

...

Keyword(s):

Molecular Weight ◽

Hydrophobic Interactions ◽

Polymer Surfaces ◽

Air Bubbles ◽

Oil Droplets

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Communication: On the Stability and Necessary Electrophoretic Mobility of Bare Oil Nanodroplets in Water

10.26434/chemrxiv.12451796 ◽

2020 ◽

Author(s):

Saranya Pullanchery ◽

Sergey Kulik ◽

halil okur ◽

Hilton. B. de Aguiar ◽

Sylvie Roke

Keyword(s):

Electrophoretic Mobility ◽

Dlvo Theory ◽

Air Bubbles ◽

Oil Droplets ◽

Cleaning Procedure ◽

Charged Droplets ◽

Oil In Water ◽

The Creation ◽

The Stability ◽

The 19Th Century

Hydrophobic oil droplets, particles and air bubbles can be dispersed in water as kinetically stabilized dispersions. It has been established since the 19th century that such objects harbor a negative electrostatic potential roughly twice larger than the thermal energy. The source of this charge continues to be one of the core observations in relation to hydrophobicity and its molecular explanation is still debated. What is clear though, is that the stabilizing interaction in these systems is understood in terms of electrostatic repulsion via DLVO theory. Recent work [Carpenter et al., PNAS 116 (2019) 9214] has added another element into the discussion, reporting the creation of bare near-zero charged droplets of oil in water that are stable for several days. Key to the creation of the droplets is a rigorous glassware cleaning procedure. Here, we investigate these conclusions and show that the cleaning procedure of glassware has no influence on the electrophoretic mobility of the droplets, that oil droplets with near-zero charge are unstable, and provide an alternative possible explanation for the observations involving glass surface chemistry.

Download Full-text