Molecular Interactions between a Biodegradable Demulsifier and Asphaltenes in an Organic Solvent

Natarajan, Anand; Kuznicki, Natalie P.; Harbottle, David; Masliyah, Jacob H.; Zeng, Hongbo; Xu, Zhenghe

doi:10.1021/acs.energyfuels.6b01889

Cited by 16 publications

(7 citation statements)

References 52 publications

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“…The resulting polymer overlap leads to an increase in osmotic pressure and repulsive interaction energy. Applying the Derjaguin approximation, the total interaction force is given by where k is the Boltzmann constant, T is the temperature, D is the surface separation distance, s is the mean distance between anchoring sites on the surface, and L is the uncompressed brush layer thickness. Since the absolute surface separation distance is unknown, the fully compressed layer thickness was estimated and used to offset the data.…”

Section: Results and Discussionmentioning

confidence: 99%

Foaming Behavior of Polymer-Coated Colloids: The Need for Thick Liquid Films

Zhang

Hodges

et al. 2017

Langmuir

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The current study examined the foaming behavior of poly(vinylpyrrolidone) (PVP)-silica composite nanoparticles. Individually, the two components, PVP and silica nanoparticles, exhibited very little potential to partition at the air-water interface, and as such, stable foams could not be generated. In contrast, combining the two components to form silica-PVP core-shell nanocomposites led to good "foamability" and long-term foam stability. Addition of an electrolyte (NaSO) was shown to have a marked effect on the foam stability. By varying the concentration of electrolyte between 0 and 0.55 M, three regions of foam stability were observed: rapid foam collapse at low electrolyte concentrations, delayed foam collapse at intermediate concentrations, and long-term stability (∼10 days) at the highest electrolyte concentration. The observed transitions in foam stability were better understood by studying the microstructure and physical and mechanical properties of the particle-laden interface. For rapidly collapsing foams the nanocomposite particles were weakly retained at the air-water interface. The interfaces in this case were characterized as being "liquid-like" and the foams collapsed within 100 min. At an intermediate electrolyte concentration (0.1 M), delayed foam collapse over ∼16 h was observed. The particle-laden interface was shown to be pseudo-solid-like as measured under shear and compression. The increased interfacial rigidity was attributed to adhesion between interpenetrating polymer layers. For the most stable foam (prepared in 0.55 M NaSO), the ratio of the viscoelastic moduli, G'/G″, was found to be equal to ∼3, confirming a strongly elastic interfacial layer. Using optical microscopy, enhanced foam stability was assessed and attributed to a change in the mechanism of foam collapse. Bubble-bubble coalescence was found to be significantly retarded by the aggregation of nanocomposite particles, with the long-term destabilization being recognized to result from bubble coarsening. For rapidly destabilizing foams, the contribution from bubble-bubble coalescence was shown to be more significant.

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Section: Results and Discussionmentioning

confidence: 99%

Foaming Behavior of Polymer-Coated Colloids: The Need for Thick Liquid Films

Zhang

Hodges

et al. 2017

Langmuir

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“…One of the most complex problems encountered in the petroleum industry is the formation of highly stable water-in-crude oil emulsions and, in fewer cases, multiple emulsions. , The formation and stabilization of such systems are mainly attributed to the presence of the naturally occurring surface active species such as asphaltenes, resins, naphthenic acids, and solid particles such as clays. − The mechanisms involved in the long term stability of these colloidal systems is commonly attributed to the formation of an elastically dominated solid-like interface that hinders coalescence and retards film drainage. Asphaltene crowding, self-association, multilayer buildup, and resin co-adsorption are some of the key parameters that dominate this phenomenon besides their ability to reduce the interfacial tension. − Another particular aspect of the rigid asphaltene layer is that it exhibits a yield stress that is significantly greater than the stress typically prompted by droplet–droplet interactions during flocculation.…”

Section: Introductionmentioning

confidence: 99%

“…One of the most complex problems encountered in the petroleum industry is the formation of highly stable water-incrude oil emulsions and, in fewer cases, multiple emulsions. 1,2 The formation and stabilization of such systems are mainly attributed to the presence of the naturally occurring surface active species such as asphaltenes, resins, naphthenic acids, and solid particles such as clays. 3−5 The mechanisms involved in the long term stability of these colloidal systems is commonly attributed to the formation of an elastically dominated solid-like interface that hinders coalescence and retards film drainage.…”

Section: ■ Introductionmentioning

confidence: 99%

Demulsifier Performance and Dehydration Mechanisms in Colombian Heavy Crude Oil Emulsions

Pradilla

Ramírez

Zanetti³

et al. 2017

Energy Fuels

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Important differences arise when chemical demulsification strategies are implemented for heavy crude oils (°API ∼ 10). Traditional methods for screening and selecting an appropriate demulsifier based on bottle tests and lipophilic–hydrophilic parameters (i.e., HLB, RSN, and so on) tend to be less adequate because of the almost negligible density difference between the oil and the water phases. This situation leads to a detriment of the separated water often mixed with undesired dense-packed layers (DPLs) and emulsion layers. In this work, dehydration of heavy crude oil emulsions from a Colombian oilfield was assessed through the use of a wide range of chemical demulsifiers of different functionalities. Through the use of bottle tests and transmission/backscattering measurements, it was shown that the demulsification mechanisms involved in these limiting cases (low density difference) are different. Hence demulsifiers with functional groups that have traditionally performed very well for lighter oils fail when applied to the heavy crude oil cases. Poly(ethylene oxide)/poly(propylene oxide) block copolymer-based products (PEO/PPO) do not seem to have the ability to penetrate the asphaltene network/film at the liquid–liquid interface (separated water, <17%) while the alkylphenol-aldehyde resins seem to prevent the formation of DPLs/emulsion layers possibly through polar interactions, yielding a good quality water phase after separation.

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“…That EC has the ability to displace and disrupt asphaltene interfacial layer agrees with the literature studies. 55,56 The recovery of the interface-dominated region implies that bulk C7 might adsorb back into the soft region created by EC, or that a restructuring of the interfacial layer occurs, increasing the film stiffness.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Effect of Ethylcellulose on the Rheology and Mechanical Heterogeneity of Asphaltene Films at the Oil–Water Interface

et al. 2019

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Asphaltenes are surface-active molecules that exist naturally in crude oil. They adsorb at the water-oil interface and form viscoelastic interfacial films that stabilize emulsion droplets, making water-oil separation extremely challenging. There is thus a need for chemical demulsifiers to disrupt the interfacial asphaltene films, and thereby facilitate water-oil separation. Here, we examine ethycellulose (EC) as a model demulsifier and measure its impact on the interfacial properties of asphaltene films using interfacial shear microrheology. When EC is mixed with an oil and asphaltene solution, it retards the interfacial stiffening that occurs between the oil phase in contact with a water phase. Moreover, EC introduces relatively weak regions within the film. When EC is introduced to a pre-existing asphaltene film, the stiffness of the films decreases abruptly and significantly. Direct visualization of interfacial dynamics further reveals that EC acts inhomogeneously, and that relatively soft regions in the initial film are seen to expand. This mechanism likely impacts emulsion destabilization, and provides new insight to the process of demulsification.

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Molecular Interactions between a Biodegradable Demulsifier and Asphaltenes in an Organic Solvent

Cited by 16 publications

References 52 publications

Foaming Behavior of Polymer-Coated Colloids: The Need for Thick Liquid Films

Foaming Behavior of Polymer-Coated Colloids: The Need for Thick Liquid Films

Demulsifier Performance and Dehydration Mechanisms in Colombian Heavy Crude Oil Emulsions

Effect of Ethylcellulose on the Rheology and Mechanical Heterogeneity of Asphaltene Films at the Oil–Water Interface

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