Hindered Nanoparticle Diffusion and Void Accessibility in a Three-Dimensional Porous Medium

Skaug, Michael J.; Wang, Liang; Ding, Yifu; Schwartz, Daniel K.

doi:10.1021/acsnano.5b00019

Cited by 88 publications

(94 citation statements)

References 54 publications

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“…14 Similar slowing of Fickian diffusion coincident with non-Gaussian distributions of particle displacements has been observed in a variety of systems, including hard sphere colloidal dispersions, 15,16 polymers in an array of pillars, 17 nanoparticles in a porous polymer matrix, 18 and colloids in a matrix of entangled F-actin polymers. Thus particle diffusion typically becomes slower in confinement.…”

Section: Introductionmentioning

confidence: 59%

Diffusive dynamics of nanoparticles in ultra-confined media

Jacob

Retterer

et al. 2015

Soft Matter

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Differential dynamic microscopy (DDM) was used to investigate the diffusive dynamics of nanoparticles of diameter 200-400 nm that were strongly confined in a periodic square array of cylindrical nanoposts. The minimum distance between posts was 1.3-5 times the diameter of the nanoparticles. The image structure functions obtained from the DDM analysis were isotropic and could be fit by a stretched exponential function. The relaxation time scaled diffusively across the range of wave vectors studied, and the corresponding scalar diffusivities decreased monotonically with increased confinement. The decrease in diffusivity could be described by models for hindered diffusion that accounted for steric restrictions and hydrodynamic interactions. The stretching exponent decreased linearly as the nanoparticles were increasingly confined by the posts. Together, these results are consistent with a picture in which strongly confined nanoparticles experience a heterogeneous spatial environment arising from hydrodynamics and volume exclusion on time scales comparable to cage escape, leading to multiple relaxation processes and Fickian but non-Gaussian diffusive dynamics.

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Section: Introductionmentioning

confidence: 59%

Diffusive dynamics of nanoparticles in ultra-confined media

Jacob

Retterer

et al. 2015

Soft Matter

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“…Different from previous studies, 4,5,20 the standard Gaussian distribution with probability density function Figure 3b. Figure 3c further shows that the tail distribution becomes more pronounced with decreasing NP size.…”

Section: The Journal Of Physical Chemistry Lettersmentioning

confidence: 65%

Probing Non-Gaussianity in Confined Diffusion of Nanoparticles

Xue

Zheng

Chen

et al. 2016

J. Phys. Chem. Lett.

103

116

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Confined diffusion is ubiquitous in nature. Ever since the “anomalous yet Brownian” motion was observed, the non-Gaussianity in confined diffusion has been unveiled as an important issue. In this Letter, we experimentally investigate the characteristics and source of non-Gaussian behavior in confined diffusion of nanoparticles suspended in polymer solutions. A time-varied and size-dependent non-Gaussianity is reported based on the non-Gaussian parameter and displacement probability distribution, especially when the nanoparticle’s size is smaller than the typical polymer mesh size. This non-Gaussianity does not vanish even at the long-time Brownian stage. By inspecting the displacement autocorrelation, we observe that the nanoparticle–structure interaction, indicated by the anticorrelation, is limited in the short-time stage and makes little contribution to the non-Gaussianity in the long-time stage. The main source of the non-Gaussianity can therefore be attributed to hopping diffusion that results in an exponential probability distribution with the large displacements, which may also explain certain processes dominated by rare events in the biological environment.

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“…We note that pressure and particularly temperature can significantly affect nanofluid properties [28], thus nanofluid behaviour and efficiency at reservoir conditions may be different; furthermore nanofluid efficiency is also likely affected by rock heterogeneity, which influences nanoparticle transport within the solid matrix [43].…”

Section: Discussionmentioning

confidence: 99%

“…All experiments were conducted at ambient conditions. At reservoir conditions, however, significantly higher pressures and elevated temperatures prevail, and as pressure and particularly temperature can affect nanofluid properties [28], nanofluid efficiency at reservoir conditions may be different to that measured at ambient conditions; furthermore, nanofluid efficiency is probably also influenced by rock heterogeneity, which determines nanofluid flow and distribution [5,43] throughout the formation.…”

Section: Introductionmentioning

confidence: 99%

Wettability alteration of oil-wet carbonate by silica nanofluid

Al-Anssari

Barifcani

Wang

et al. 2016

Journal of Colloid and Interface Science

363

243

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Changing oil-wet surfaces toward higher water wettability is of key importance in subsurface engineering applications. This includes petroleum recovery from fractured limestone reservoirs, which are typically mixed or oil-wet, resulting in poor productivity as conventional waterflooding techniques are inefficient. A wettability change toward more water-wet would significantly improve oil displacement efficiency, and thus productivity. Another area where such a wettability shift would be highly beneficial is carbon geo-sequestration, where compressed CO2 is pumped underground for storage. It has recently been identified that more water-wet formations can store more CO2. We thus examined how silica based nanofluids can induce such a wettability shift on oil-wet and mixed-wet calcite substrates. We found that silica nanoparticles have an ability to alter the wettability of such calcite surfaces. Nanoparticle concentration and brine salinity had a significant effect on the wettability alteration efficiency, and an optimum salinity was identified, analogous to that one found for surfactant formulations. Mechanistically, most nanoparticles irreversibly adhered to the oil-wet calcite surface (as substantiated by SEM-EDS and AFM measurements). We conclude that such nanofluid formulations can be very effective as enhanced hydrocarbon recovery agents and can potentially be used for improving the efficiency of CO2 geo-storage.

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Hindered Nanoparticle Diffusion and Void Accessibility in a Three-Dimensional Porous Medium

Cited by 88 publications

References 54 publications

Diffusive dynamics of nanoparticles in ultra-confined media

Diffusive dynamics of nanoparticles in ultra-confined media

Probing Non-Gaussianity in Confined Diffusion of Nanoparticles

Wettability alteration of oil-wet carbonate by silica nanofluid

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