Study of Nanoparticle Adsorption and Release in Porous Media Based on the DLVO Theory

Abdelfatah, Elsayed; Kang, Kyung-Ku; Pournik, Maysam; Shiau, Bor-Jier; Harwell, Jeffrey H.; Haroun, Mohammed; Rahman, Motiur

doi:10.2118/185484-ms

Cited by 27 publications

(11 citation statements)

References 37 publications

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“…The improvement in oil recovery when NPs are injected into the reservoir is attributed to the variation in the wettability alteration, ,,− the interfacial tension, ,, and the rheological properties. − Several studies have revealed that the viscosity of the fluid increases with increasing concentration of NPs at different temperatures. ,,, Mishra et al explained that different factors, such as type of base fluids, particle shape, temperature, shear rate, pH value, and dispersion, have an impact on the viscosity of the nanofluid. Sahoo et al and Namburu et al showed that aluminum oxide NPs exhibit non-Newtonian behavior at low temperatures (238–273 K) and Newtonian behavior at temperatures above 273 K. Di Giuseppe et al explained that the change in the viscosity of nanofluids from Newtonian to non-Newtonian behavior is attributed to the change in the electrical double layer (EDL) by the particle volume fraction.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study on the Viscosity Behavior of Silica Nanofluids with Different Ions of Electrolytes

Olayiwola

Dejam

2020

Ind. Eng. Chem. Res.

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Understanding the mechanisms behind the interaction between the nanoparticles (NPs) and the brine/seawater is critical for successful oil recovery. In this study, the effect of ionic components of brine, including Na + , K + , Ca 2+ , Mg 2+ , Cl − , and SO 4 2− , at different concentrations of silica NPs on the viscosity of the fluid is investigated for the first time. A comprehensive experimental study on the mechanisms behind the variation in the viscosity of silica nanofluids is presented. The results show that the cations present in the electrolytes increase the viscosity of silica nanofluids in the order of Na > Mg > K > Ca while the electrolytes with SO 4 2− ion have a higher viscosity than those with Cl − ion. The interaction between the ions of silica NPs and electrolytes is classified into three different regions. In region I, the measured energy-dispersive X-ray of the transmission electron microscopy image shows that an interaction between the ions of silica NPs and the electrolyte anions in the electrical double layer results in the formation of a complex compound. In regions II and III, the electrolyte forms a protective layer on the silica NPs to isolate them from one another. The average size of particles in the nanofluid at a fixed concentration of electrolytes in regions II and III decreases at concentrations of silica NPs beyond the peak value, but only region I is observed at a constant concentration of silica NPs and varying electrolyte concentrations. These findings can improve the design and implementation of NPs for an efficient oil recovery.

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Section: Introductionmentioning

confidence: 99%

Experimental Study on the Viscosity Behavior of Silica Nanofluids with Different Ions of Electrolytes

Olayiwola

Dejam

2020

Ind. Eng. Chem. Res.

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“…The Derjaguin–Landau–Verwey–Overbeek (DLVO) theory studies the applied forces on charged particles in a colloidal fluid medium and examines the tendency of particles to agglomerate or remain as separate particles. − Figure shows the different forces acting upon particles in a fluid medium based on the DLVO theory.…”

Section: Chemical Treatment For Sand Controlmentioning

confidence: 99%

A Review on Chemical Sand Production Control Techniques in Oil Reservoirs

et al. 2022

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This review aims to bring together the studies on petroleum reservoirs’ sand production control in a comprehensive guide for the researcher to compare various methods for the chemical consolidation of sand. Sand production can be considered one of the major challenges in the petroleum production industry, causing severe operational issues. This study introduces various methods to control and prevent sand production in petroleum wells and evaluates their advantages and performance in tabular form. The use of chemical procedures is considered to be more efficient in counteracting the production and migration of sand. Various chemicals and polymers have been proposed for this purpose. These chemicals should increase the consolidation of the formation rock while not reducing its permeability. The complexity and simplicity of the substances will be the two main factors. Novelties are generally tied with complex chemical structures. Conversely, simplicity makes them affordable, which is essential for industrialization. Success is obtained when the two are combined. This Review is expected to allow individual experts to compare various methods and be a handbook guiding them in the pursuit of finding the appropriate method of sand control for each reservoir.

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“…Nanoparticles are generally small that they easily move within the pores of rock materials without plugging it, but sometimes due to affinity for one another, the nanoparticles are retained on the rock surface. On the bases of Derjaguin, Landau, Verwey, and Overbeek (DLVO) theory, Abdelfatah et al (2017) came up with theoretical equations that calculated the deposition and release rate under different ionic strengths, pH and temperature conditions. The authors developed a model to determine Zeta potential of rock and nanoparticles at different conditions and validated it with an experiment that determines the rate at which silica nanoparticles are deposited and released on sandstone formation.…”

Section: Nanoparticle Adsorptionmentioning

confidence: 99%

A review on polymer, gas, surfactant and nanoparticle adsorption modeling in porous media

Mohammed

Afagwu

Adjei

et al. 2020

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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Adsorption is a rock surface phenomenon and has increasingly become popular, especially in particle-transport applications across many fields. This has drawn a remarkable number of publications from the industry and academia in the last decade, with many review articles focused on adsorption of polymers, surfactants, gas, and nanoparticles in porous media with main applications in Enhanced Oil Recovery (EOR). The discussions involved both experimental and modeling approaches to understanding and efficiently mimicking the particle transport in a bid to solve pertinent problems associated with particle retention on surfaces. The governing mechanisms of adsorption and desorption constitute an area under active research as many models have been proposed but the physics has not been fully honored. Thus, there is a need for continuous research effort in this field. Although adsorption/desorption process is a physical phenomenon and a reversible process resulting from inter-molecular and the intramolecular association between molecules and surfaces, modeling these phenomena requires molecular level understanding. For this reason, there is a wide acceptance of molecular simulation as a viable modeling tool among scientists in this area. This review focuses on existing knowledge of adsorption modeling as it relates to the petroleum industry cutting across flow through porous media and EOR mostly involving polymer and surfactant retention on reservoir rocks with the associated problems. The review also analyzes existing models to identify gaps in research and suggest some research directions to readers.

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Study of Nanoparticle Adsorption and Release in Porous Media Based on the DLVO Theory

Cited by 27 publications

References 37 publications

Experimental Study on the Viscosity Behavior of Silica Nanofluids with Different Ions of Electrolytes

Experimental Study on the Viscosity Behavior of Silica Nanofluids with Different Ions of Electrolytes

A Review on Chemical Sand Production Control Techniques in Oil Reservoirs

A review on polymer, gas, surfactant and nanoparticle adsorption modeling in porous media

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