Separation of Viscous Oil Emulsions Using Three-Dimensional Nanotetrapodal ZnO Membranes

O'Loughlin, Thomas E.; Ngamassi, Frank-Eric; McKay, P. F.; Banerjee, Sarbajit

doi:10.1021/acs.energyfuels.8b00235

Cited by 13 publications

(29 citation statements)

References 36 publications

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“…The coating scores 5B in ASTM 3359 and can withstand scrape testing up to 20–30 g in ASTM 2197. In other formulations, we have seen significant improvement in the stability upon deposition of an amorphous SiO 2 layer (>1 kg in ASTM 2197). , The coatings are thus suitable for applications in nonabrasive environments.…”

Section: Results and Discussionmentioning

confidence: 99%

“…For instance, liquid-impregnated coatings show promising performance but are readily damaged and difficult to scale; lithographically patterned architectures provide precise control of re-entrant curvature, but their elaboration to macroscopic scales remains challenging; polymeric coatings, such as block copolymers, enable definition of tailored chemical domains but have inadequate thermal stability and are prone to fouling. In previous work, we have demonstrated the promise of ceramic/metal coatings comprising ZnO tetrapods sprayed onto metal mesh surfaces; surface functionalization of the tetrapods yields hydrophobic/oleophobic, hydrophilic/oleophobic, or hydrophobic/oleophilic , character, enabling applications ranging from gliding of viscous oils to the separation of recalcitrant water/oil emulsions. The ZnO tetrapods serve to amplify the intrinsic wettability of the surface monolayers and yield 3D interconnected plastronic architectures that extend into the pores of the metal meshes, with the meshes additionally providing periodic micron-scale texture.…”

Section: Introductionmentioning

confidence: 99%

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Three-Dimensional Inverse Opal TiO₂ Coatings to Enable the Gliding of Viscous Oils

et al. 2020

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As a result of the increasing emphasis on accessing unconventional deposits of heavy oil and bitumen to meet global energy needs, there is an intense focus on addressing the rheological challenges involved in the transportation, handling, and processing of viscous hydrocarbons. While the design of superhydrophobic surfaces has been extensively explored, the fabrication of surfaces nonwetted by low-surface-tension and high-viscosity oils that can be scaled to meet industrial needs remains to be adequately addressed. Here, we demonstrate that colloidally templated architectures of TiO2 particles applicable through a facile spray deposition process can form 3D inverse opal coatings adhered to low-alloy steels. Low-temperature sintering induces necking of particles, giving rise to an interconnected framework of plastrons surrounded by necked TiO2 ligaments. Surface functionalization with 1H,1H,2H,2H-perfluorooctanephosphonic acid yields a helical surface monolayer with pendant trifluoromethyl moieties. The combination of interconnected plastrons, re-entrant curvature, and low surface energy suspends liquid droplets, of both water and heavy oil, in the Cassie–Baxter regime, yielding contact angles of 164° ± 5° and 161° ± 2°, respectively. The interconnected network of plastrons further enables the facile gliding of heavy oil (<100 s) upon immersion within a bath, whereas a comparable untreated surface remains completely fouled. The performance of this coating suggests a promising solution to mitigate the challenges of handling viscous oils in midstream applications and furthermore delineates a route to designing coatings for a broad host of rheologically challenging fluids.

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Section: Results and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Three-Dimensional Inverse Opal TiO₂ Coatings to Enable the Gliding of Viscous Oils

et al. 2020

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“…Despite achieving big achievement in emulsion separation, few of them are applicable for the separation of viscous water-in-crude oil emulsions. , This is because of the high viscosity of crude oil, which always causes a slow diffusion of viscous crude oil into the membrane pores. More seriously, the high viscosity and adhesive property result in a low permeation rate, pores fouling, and inefficient separation and even lead to the invalidation of related instruments. , In addition, the fabrication process of such superhydrophobic membranes is rather complicated. , Therefore, it is urgent to develop a facile and efficient superhydrophobic separation membrane to decrease the viscosity, thus enhancing the fluidity of emulsions for achieving separation of viscous water-in-crude oil emulsions.…”

Section: Introductionmentioning

confidence: 99%

“…More seriously, the high viscosity and adhesive property result in a low permeation rate, pores fouling, and inefficient separation and even lead to the invalidation of related instruments. 23,24 In addition, the fabrication process of such superhydrophobic membranes is rather complicated. 25,26 Therefore, it is urgent to develop a facile and efficient superhydrophobic separation membrane to decrease the viscosity, thus enhancing the fluidity of emulsions for achieving separation of viscous water-in-crude oil emulsions.…”

Section: Introductionmentioning

confidence: 99%

Superhydrophobic Stainless-Steel Mesh with Excellent Electrothermal Properties for Efficient Separation of Highly Viscous Water-in-Crude Oil Emulsions

Yue

Zhang

et al. 2020

Ind. Eng. Chem. Res.

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The separation of tiny water droplets from viscous crude oil is urgently needed and still remains a substantial challenge because of severe membrane fouling resulting from the high viscosity and adhesive property of crude oil. To solve this issue, the electrothermal effect, for the first time, was utilized to heat the water-in-crude oil emulsion using electrical current as an energy source to extremely reduce the viscosity of the water-in-crude oil emulsion and thus to realize efficient viscous emulsion separation. A silicone-modified stainless-steel mesh (SSM) was fabricated via coating silicone on the SSM and transient heating. The as-prepared silicone-modified SSM allows for an outstanding integration of superhydrophobic/superoleophilic properties from the partial thermal degradation of the silicone coating and superior electrothermal capability from SSM. Thanks to the excellent electrothermal capability, the silicone-modified SSM achieved a high electrothermal power density of 3.43 W cm–2 at a low input voltage of 5 V. The resulting Joule heating, superhydrophobicity, and micropore structure enabled the silicone-modified SSM to efficiently separate a viscous water-in-crude oil emulsion (2.6 × 104 mPa s at 20 °C) with high separation efficiency (98.9%) and separation flux (314 L m–2 h–1). Moreover, the silicone-modified SSM presented optimal reusability and stability after six cycles for the viscous water-in-crude oil emulsion. This electrothermal-assisted viscous emulsion separation strategy can provide some new perspectives for viscous oil/water emulsion separation.

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“…Current limitations in processing of mixed water/oil streams and remediation of oil spills include low separation efficiencies, generation of secondary pollutants from sloughing of sorbent materials, need for energy-intensive processes, high cost, and potential ecological toxicity of membrane materials. Considerable recent attention has been focused on the design of membranes for realizing water/oil separation based on differential affinity, density, flow characteristics, and wettability. ,,, In a previous work, we have demonstrated the design of superoleophilic and superhydrophobic membranes comprising ZnO nanotetrapods integrated onto stainless steel meshes. , The membranes permit the high-efficiency separation of water/oil emulsions, including challenging viscous oil emulsions stabilized by endogenous surfactants extracted from the Alberta oil sands using the steam-assisted gravity drainage (SAGD) process. Notably, such membranes are fully compatible with the high-temperature operation required to crack the emulsions .…”

Section: Introductionmentioning

confidence: 99%

Functionalized Tetrapodal ZnO Membranes Exhibiting Superoleophobic and Superhydrophilic Character for Water/Oil Separation Based on Differential Wettability

et al. 2019

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Achieving the efficacious and rapid separation of mixed water/oil streams has emerged as a fundamental imperative in order to facilitate extraction of fossil fuels by methods such as cyclic steam stimulation as well as to mitigate the potentially calamitous impact of oil spills in natural aquatic environments. Here, we demonstrate functionalized ZnO nanotetrapodal membranes combining the micrometer-scale texturation of underlying stainless steel meshes with the nanoscale texturation of an enmeshed interconnected porous network of ZnO tetrapods, the conformal adhesion afforded by an amorphous silica layer, and the low surface energy of surface-deposited perfluorinated sulfonate layers. The membranes exhibit pronounced differential wettability and selectively permeate water whilst retaining oil. The multivariate design space of the architectures has been evaluated to determine the mesh size and ZnO loading that yield the highest separation efficiencies. Oil content in recovered water is reduced to <300 ppm while maintaining a flux rate of greater than 325 L/(m 2 •h). The functioning of the membranes can be understood in terms of the creation of differential Cassie−Baxter nonwetting and Wenzel wetting regimes for oil and water, respectively.

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Separation of Viscous Oil Emulsions Using Three-Dimensional Nanotetrapodal ZnO Membranes

Cited by 13 publications

References 36 publications

Three-Dimensional Inverse Opal TiO₂ Coatings to Enable the Gliding of Viscous Oils

Three-Dimensional Inverse Opal TiO₂ Coatings to Enable the Gliding of Viscous Oils

Superhydrophobic Stainless-Steel Mesh with Excellent Electrothermal Properties for Efficient Separation of Highly Viscous Water-in-Crude Oil Emulsions

Functionalized Tetrapodal ZnO Membranes Exhibiting Superoleophobic and Superhydrophilic Character for Water/Oil Separation Based on Differential Wettability

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Separation of Viscous Oil Emulsions Using Three-Dimensional Nanotetrapodal ZnO Membranes

Cited by 13 publications

References 36 publications

Three-Dimensional Inverse Opal TiO2 Coatings to Enable the Gliding of Viscous Oils

Three-Dimensional Inverse Opal TiO2 Coatings to Enable the Gliding of Viscous Oils

Superhydrophobic Stainless-Steel Mesh with Excellent Electrothermal Properties for Efficient Separation of Highly Viscous Water-in-Crude Oil Emulsions

Functionalized Tetrapodal ZnO Membranes Exhibiting Superoleophobic and Superhydrophilic Character for Water/Oil Separation Based on Differential Wettability

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Three-Dimensional Inverse Opal TiO₂ Coatings to Enable the Gliding of Viscous Oils

Three-Dimensional Inverse Opal TiO₂ Coatings to Enable the Gliding of Viscous Oils