Formation and Stability of Bulk Nanobubbles in Different Solutions

Ke, Shuo; Xiao, Weiqiang; Quan, Nannan; Dong, Yaming; Zhang, Lijuan; Hu, Jun

doi:10.1021/acs.langmuir.9b00144

Cited by 70 publications

(74 citation statements)

References 63 publications

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“…Total reflectance infrared spectroscopy of nanobubble solutions indicated the presence of hard hydrogen bonds equivalent to those found in ice and gas hydrates [39]. It has been reported that bulk nanobubbles 50-500 nm in diameter can be prepared by pressurizing gas in water and then decompressing the water to ambient pressure [40,41]. Thus, bulk nanobubbles may be present in the gas-supersaturated water that we prepared here.…”

Section: Chemical Science Accepted Manuscriptmentioning

confidence: 65%

“…The existence and stability of bulk nanobubbles have been highly debated. To date, numerous experimental studies have shown that bulk nanobubbles can be stable in water for hours or even weeks [3,[39][40][41]. Those studies mainly employed optical methods, which lack the resolution to see detailed structures in "nanobubbles".…”

Section: Chemical Science Accepted Manuscriptmentioning

confidence: 99%

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Investigating states of gas in water encapsulated between graphene layers

Hsu

Hwang

2021

Chem. Sci.

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Section: Chemical Science Accepted Manuscriptmentioning

confidence: 65%

Section: Chemical Science Accepted Manuscriptmentioning

confidence: 99%

Investigating states of gas in water encapsulated between graphene layers

Hsu

Hwang

2021

Chem. Sci.

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“…DLS is most commonly used to determine the diameter of bubbles in liquid but allows only for the size distribution density measurement without the number concentration. NTA is potentially able to determine the concentration of bubbles (Oh et al ., 2015; Oh and Kim, 2017; Qiu et al ., 2017; Hu and Xia, 2018; Ke et al ., 2019). However, huge errors can be made using this method as the operator has to set the background level oneself.…”

Section: Nanodispersion Properties and Their Measurementmentioning

confidence: 99%

Gas nanobubble dispersions as the important agent in environmental processes – generation methods review

Ulatowski

Sobieszuk

2020

Water & Environment J

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This article presents the review of the research papers concerning nanobubble generation. In main section of this article, numerous methods of nanobubble generation have been discussed pinpointing the differences in results obtained in similar experimental setups. Different generation methods have been tabularized to present the composition of phases, the diameter of generated bubbles as well as the commentary concerning discrepancies within one method. The number of nanobubble applications in environmental processes is increasing in the last year; however, the thorough investigation of their generation methods is not covered in literature. This review article is gathering knowledge about nanobubble generation methods and is comparing results obtained by different research teams. It should lay foundation for future research concerning nanobubbles, what will lead to increasing the efficiency of various environmental processes, including wastewater flotation, metal recovery, and soil and groundwater remediation. Gas nanobubble dispersions as the important agent in environmental processes K. Ulatowski and P. Sobieszuk

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“…Three common methods of exploring hydrodynamic cavitation are used to generate nanobubbles in flotation research: high intensity conditioning; fast liquid flow through a cavitation tube; and gas super‐saturation under dynamic conditions. While conventional particle size analyzers are used to detect the sizes of nanobubbles generated, the most commonly used method for estimating the population of nanobubbles is a nanoparticle tracking analysis (NTA) instrument, which is based on light scattering . In a high intensity agitation cell, the population of nanobubbles increased with increasing agitation speed, due to more intensified hydrodynamic cavitation at a higher agitation speed .…”

Section: Generation Of Micro‐nanobubblesmentioning

confidence: 99%

“…While conventional particle size analyzers are used to detect the sizes of nanobubbles generated, the most commonly used method for estimating the population of nanobubbles is a nanoparticle tracking analysis (NTA) instrument, which is based on light scattering. [142][143][144][145][146] In a high intensity agitation cell, the population of nanobubbles increased with increasing agitation speed, due to more intensified hydrodynamic cavitation at a higher agitation speed. [142,143] As shown in Figure 9, the size of nanobubbles generated dramatically decreased from 820 to 200 nm with an increasing agitation rate.…”

Section: Generation and Characterization Of Nanobubblesmentioning

confidence: 99%

Role of mineral flotation technology in improving bitumen extraction from mined Athabasca oil sands—II. Flotation hydrodynamics of water‐based oil sand extraction

Zhou¹,

HaiHong²,

Chow³

et al. 2019

Can J Chem Eng

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Bitumen flotation hydrodynamics in water‐based oil sand extraction is critically reviewed by comparing aeration of oil sand slurries with mineral flotation. The role of the two‐stage particle‐bubble attachment model in flotation is emphasized as a means to accelerate bitumen flotation recovery. It involves the generation of micro/nanobubbles and their frosting on hydrophobic bitumen droplets, followed by their attachment to a flotation‐size bubble via its coalescence with the nanobubbles frosted on the bitumen. Nanobubble generation by hydrodynamic cavitation demonstrates that the size of nanobubbles can be reduced, and the number of nanobubbles increased by fast liquid flow, intensified agitation, high dissolved gas content and surfactant concentration. The mechanism of pre‐existing gas nuclei in enhancing nanobubble generation by cavitation is utilized to produce a large volume of stabilized nanobubbles for practical flotation, by continuously recirculating the stream through a gas saturation tank or a cavitation tube. The aeration of oil sand slurries in hydrotransport pipelines is analyzed based on its similarity to dissolved air flotation. Bitumen extraction recovery increased significantly with the presence of nanobubbles in the system. The role of improved flotation hydrodynamics in bitumen recovery is briefly discussed in terms of the Suncor operation using flotation columns to process oil sand middling streams. Future research should be directed at understanding bitumen flotation kinetics, optimizing size ranges of nanobubbles for maximized flotation recovery, minimizing wearing of cavitation tubes in industrial operations, and intensifying the role of in‐situ nanobubble nucleation on hydrophobic particles/bitumen droplets in flotation, especially for bitumen extraction from underperforming oil sands.

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Formation and Stability of Bulk Nanobubbles in Different Solutions

Cited by 70 publications

References 63 publications

Investigating states of gas in water encapsulated between graphene layers

Investigating states of gas in water encapsulated between graphene layers

Gas nanobubble dispersions as the important agent in environmental processes – generation methods review

Role of mineral flotation technology in improving bitumen extraction from mined Athabasca oil sands—II. Flotation hydrodynamics of water‐based oil sand extraction

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