Precisely Tailoring Bubble Morphology in Microchannel by Nanoparticles Self-assembly

Wu, Yining; Wang, Ruoyu; Dai, Caili; Xu, Yan; Yue, Tongtao; Zhao, Mingwei

doi:10.1021/acs.iecr.8b06057

Cited by 33 publications

(13 citation statements)

References 23 publications

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“…The relatively low resistance of silica nanofluids to temperature and salt aggravates the aggregation and precipitation after long-time use, which probably gives rise to the blockage of the pore-throats structure underground causing formation pollution (Das 2009). To overcome this problem, methods for preparing uniform and stable nanofluids are constantly developed (Li et al 2011;Babita and Gupta 2016), including physical and chemical modification methods (Esfandyari et al 2014;Arulprakasajothi et al 2015;Wu et al 2019). Tushar et al prepared nanofluids by adding polymers (Arulprakasajothi et al 2015) and proved that polymer can enhance nanofluids stability.…”

Section: Introductionmentioning

confidence: 99%

Preparation and stabilization mechanism of carbon dots nanofluids for drag reduction

Cao

et al. 2020

Pet. Sci.

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During the development of low or ultra-low permeability oil resources, the alternative energy supply becomes a prominent issue. In recent years, carbon dots (CDs) have drawn much attention owing to their application potential in oil fields for reducing injection pressure and augmenting oil recovery. However, carbon dots characterized of small size, high surface energy are faced with several challenges, such as self-aggregation and settling. The preparation of stably dispersed carbon dots nanofluids is the key factor to guarantee its application performance in formation. In this work, we investigated the stability of hydrophilic carbon dots (HICDs) and hydrophobic carbon dots–Tween 80 (HOCDs) nanofluids. The influences of carbon dots concentration, sorts and concentration of salt ions as well as temperature on the stability of CDs were studied. The results showed that HICDs are more sensitive to sort and concentration of salt ions, while HOCDs are more sensitive to temperature. In addition, the core flooding experiments demonstrated that the pressure reduction rate of HICDs and HOCDs nanofluids can be as high as 17.88% and 26.14%, respectively. Hence, the HICDs and HOCDs nanofluids show a good application potential in the reduction of injection pressure during the development of low and ultra-low permeability oil resources.

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Section: Introductionmentioning

confidence: 99%

Preparation and stabilization mechanism of carbon dots nanofluids for drag reduction

Cao

et al. 2020

Pet. Sci.

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“…Stolovicki et al 10 found that the uniformity of the droplet's size deteriorated with the increase of the flow rate of the dispersed phase. Mittal et al 9 found that the coalescence between droplets is the key factor affecting the uniformity of droplets’ volume 13 …”

Section: Introductionmentioning

confidence: 99%

Mesoscale effect on bubble formation in step‐emulsification devices with two parallel microchannels

Jiang

Zhu

et al. 2020

AIChE Journal

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The step‐emulsification devices with parallel microchannels are promising for the high‐throughput formation of bubbles. However, the mechanism for bubble formation in such devices remains unclear. In present study, the mesoscale concept of compromise in a competition is used to reveal the mechanism. Nitrogen is used as the dispersed phase, and aqueous solutions with different viscosities are used as the continuous phase. The flow patterns and characteristic parameters for bubble formation are studied by using a high‐speed camera. The characteristic parameters include the head distance of gas–liquid interface and the neck width, and the size and formation frequency of bubbles. Bubble formation is affected by the hydrodynamic feedback in the chamber and the interfacial evolution process, characterized by the relative magnitude of the evolution velocity for the head distance and the neck width of gaseous thread in both microchannels. It is found that the compromise effect is beneficial for the formation of bubbles with excellent monodispersity.

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“…Recent development of microfluidic devices allows the study of flow behaviors of viscoelastic fluids in micro pore unit directly 27‐31 . Researchers are able to analyze quantitatively the velocity fields of viscoelastic fluids, 32 migration of crude oil droplet, 33 and interface merging or breakup of bubble 34 .…”

Section: Introductionmentioning

confidence: 99%

Viscoelastic surfactant fluids filtration in porous media: A pore‐scale study

Dai

et al. 2020

AIChE Journal

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We investigated the flow of viscoelastic surfactant (VES) solutions, an important type of fracturing fluids for unconventional hydrocarbon recovery, through a divergingconverging microfluidic channel that mimics realistic unit in porous media. Newtonian fluid and viscoelastic hydrolyzed polyacrylamide (HPAM) solution were used as control groups. We vary Deborah numbers (De) up to 61.2, and found that the flow patterns of HPAM and VES solutions become very different once De ≥ 6.12. This is attributed to different generation mechanisms of viscoelasticity, thus different responses to extensional rates at pore-throats, for HPAM and VES solutions. It results in significantly smaller pressure drop of VES solutions through the microchannel compared to HPAM solution. It interprets higher filtration loss of VES solution than HPAM in core experiments and in field observations. The set-up can be generalized as a prototype to effectively evaluate the filtration of fracturing fluids.

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Precisely Tailoring Bubble Morphology in Microchannel by Nanoparticles Self-assembly

Cited by 33 publications

References 23 publications

Preparation and stabilization mechanism of carbon dots nanofluids for drag reduction

Preparation and stabilization mechanism of carbon dots nanofluids for drag reduction

Mesoscale effect on bubble formation in step‐emulsification devices with two parallel microchannels

Viscoelastic surfactant fluids filtration in porous media: A pore‐scale study

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