Modeling the Assembly of Polymer-Grafted Nanoparticles at Oil–Water Interfaces

Yong, Xin

doi:10.1021/acs.langmuir.5b03405

Cited by 39 publications

(61 citation statements)

References 69 publications

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“…This can be demonstrated by a high linear correlation coefficient R 2 =0.9908. This also proved that the sorption of oil on the grafted fibers was monolayer sorption [53,54]. From the obtained equation (Figure 10), we can identify the maximum oil sorption capacity is Q max =1/0.048=20.833 (g/g).…”

Section: Determination Of the Maximum Absorption Capacitysupporting

confidence: 53%

Oil Sorbents based on Methacrylic Acid - Grafted Polypropylene Fibers: Synthesis and Characterization

Ha¹,

Sơn²

2016

J Chem Eng Process Technol

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Section: Determination Of the Maximum Absorption Capacitysupporting

confidence: 53%

Oil Sorbents based on Methacrylic Acid - Grafted Polypropylene Fibers: Synthesis and Characterization

Ha¹,

Sơn²

2016

J Chem Eng Process Technol

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“…Molecular simulations predict that the conformation of ligands grafted onto the NP surface can change upon adsorption to the interface due to the asymmetric environment surrounding the particles . Yong characterized the adsorption process, i.e., approaching and breaching of the interface, and subsequent change in conformation, of polymer‐grafted NPs via molecular simulation . They observed that grafted chains can undergo significant reconfiguration during adsorption by spreading onto the interface to maximize the reduction in surface tension (Figure a–f), indirect evidence for which has also been seen experimentally .…”

Section: Assembly Dynamics and In Situ Characterization Of Nanomatementioning

confidence: 70%

Section: Assembly Dynamics and In Situ Characterization Of Nanomatementioning

confidence: 99%

Building Reconfigurable Devices Using Complex Liquid–Fluid Interfaces

et al. 2019

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imparts novel mechanical and functional properties to the macroscopic interface itself. These properties include size-and charge-selective pathways for molecules and particulates, shear and compressive moduli, and selective binding and reaction sites. Complex interfaces can then be used to generate complex, macroscopic, all-liquid materials with very high surface areas that have unique properties, such as compartmentalization, communication between compartments, and the ability to move and reconfigure. With the rapid growth in the study of complex materials made from interfacially structured liquids, there is a need to review the field from the funda-Liquid-fluid interfaces provide a platform both for structuring liquids into complex shapes and assembling dimensionally confined, functional nanomaterials. Historically, attention in this area has focused on simple emulsions and foams, in which surface-active materials such as surfactants or colloids stabilize structures against coalescence and alter the mechanical properties of the interface. In recent decades, however, a growing body of work has begun to demonstrate the full potential of the assembly of nanomaterials at liquid-fluid interfaces to generate functionally advanced, biomimetic systems. Here, a broad overview is given, from fundamentals to applications, of the use of liquid-fluid interfaces to generate complex, all-liquid devices with a myriad of potential applications. Figure 2.Interactions between particles attached to liquid-fluid interfaces. a) Dipole-dipole interactions between adsorbed particles due to asymmetric charge distributions near the surface of particles at interfaces. Reproduced with permission. [34] Copyright 1980, American Physical Society. b) Dipole-dipole interactions give rise to 2D colloidal crystals with large lattice spacings. Scale bar, 50 µm. Reproduced with permission. [36]

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“…Meanwhile, experimental results by Wasan and Nikolov [26] showed that the nanoparticles could form two-dimensional (2-D) layered structures in the confines of the three-phase (solid-oil-aqueous phase) contact region and produce disjoining pressure that leads to the wettability alteration of the solid phase. Therefore, it has been believed that nanoparticles can change the interfacial tension, viscosity and wettability of fluids, which are important to many applications ranging from electronics cooling to oil recovery [30][31][32][33][34]. However, due to the additional particle-particle, particle-capillary and particle-fluid interactions [32,35], the presence of nanoparticles leads to a much more complicated imbibition process compared with pure fluids.…”

Section: Introductionmentioning

confidence: 99%

Effect of Nanoparticles on Spontaneous Imbibition of Water into Ultraconfined Reservoir Capillary by Molecular Dynamics Simulation

et al. 2017

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Imbibition is one of the key phenomena underlying processes such as oil recovery and others. In this paper, the influence of nanoparticles on spontaneous water imbibition into ultraconfined channels is investigated by molecular dynamics simulation. By combining the dynamic process of imbibition, the water contact angle in the capillary and the relationship of displacement (l) and time (t), a competitive mechanism of nanoparticle effects on spontaneous imbibition is proposed. The results indicate that the addition of nanoparticles decreases the displacement of fluids into the capillary dramatically, and the relationship between displacement and time can be described by l(t) t 1/2. Based on the analysis of the dynamic contact angle and motion behavior of nanoparticles, for water containing hydrophobic nanoparticles, the displacement decreases with the decrease of hydrophobicity, and the properties of fluids, such as viscosity and surface tension, play a major role. While for hydrophilic nanoparticles, the displacement of fluids increases slightly with the increase of hydrophilicity in the water-wet capillary and simulation time, which can be ascribed to disjoining pressure induced by "sticking nanoparticles". This study provides new insights into the complex interactions between nanoparticles and other components in nanofluids in the spontaneous imbibition, which is crucially important to enhanced oil recovery.

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Modeling the Assembly of Polymer-Grafted Nanoparticles at Oil–Water Interfaces

Cited by 39 publications

References 69 publications

Oil Sorbents based on Methacrylic Acid - Grafted Polypropylene Fibers: Synthesis and Characterization

Oil Sorbents based on Methacrylic Acid - Grafted Polypropylene Fibers: Synthesis and Characterization

Building Reconfigurable Devices Using Complex Liquid–Fluid Interfaces

Effect of Nanoparticles on Spontaneous Imbibition of Water into Ultraconfined Reservoir Capillary by Molecular Dynamics Simulation

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