On the influence of heterogeneity of graphene sheets in the determination of the pore size distribution of activated carbons

Oliveira, José Carlos; López, Ramírez; Toso, Juan Pablo; Lucena, Sebastião M. P.; Cavalcante, Célio L.; Azevedo, Diana C. S.; Zgrablich, G.

doi:10.1007/s10450-011-9343-5

Cited by 21 publications

(6 citation statements)

References 20 publications

(22 reference statements)

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“…Among the models proposed in the literature for activated carbon (Do and Do 2006;Lucena et al 2008Lucena et al , 2017Nguyen et al 2008;Oliveira et al 2011), we choose the most used model. The molecular representation of activated carbon is then de ned as slits of graphene layers walls.…”

Section: Methodsmentioning

confidence: 99%

Prediction of chlorophenols adsorption on activated carbons by representative pores method

Oliveira

Rodrigues

Lucena

2022

Environ Sci Pollut Res

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The speci cation of a particular activated carbon adsorbents for removal of phenol and related derivatives, from dilute aqueous solutions, is still based on lengthy trial and error experimental tests. A predictive model of adsorption of these compounds would considerably reduce the carbon selection time and could also bring new information to support more e cient carbon synthesis. The use of molecular simulation and the methodology of representative pores, proved to be adequate for quantitative prediction of phenol adsorption. Here the methodology is being extended to chlorophenols, an important class of phenol-derived pollutants. A set of ortho and para-chlorophenol isotherms were simulated for different representative pores in order to predict carbon adsorption and determine the most signi cative pore size. At low concentrations (1x10 -4 mol/L), the pores of 8.9 and 18.5 Å are the most effective. For concentrations above 3 x10 -4 mol/L pores in the range of 27.9 Å must be present in the activated carbon.The adsorption isotherm difference between ortho and para-chlorophenol, identi ed experimentally, was reproduced in the simulation and its origin was investigated further. Finally, the adsorption isotherms of chlorophenols for other activated carbons were predicted with the help of the model.

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Section: Methodsmentioning

confidence: 99%

Prediction of chlorophenols adsorption on activated carbons by representative pores method

Oliveira

Rodrigues

Lucena

2022

Environ Sci Pollut Res

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“…where, for one-component adsorption, the bulk gas phase composition y is equal to one (Heuchel et al 1999); N i ex (H,T,P,y) is the excess number of adsorbed molecules of species i in a model pore of width H at temperature T, pressure P and bulk gas-phase composition y; N i abs (H,T,P,y) is the N H T P y N H T P y y is the bulk fluid density of species i at the temperature and pressure of concern; and V bf (H) is the volume in the model pore of width H accessible to the bulk fluid (Oliveira et al 2011). The calculations were performed at a defined temperature and pressure by using the equation of state for ideal gases at low pressures (up to 0.1 MPa) and the Peng-Robinson equation of state (1976) for high pressures, employing the parameters listed in Table 2 (Sandler 1989).…”

Section: Gcmc Analysis Of Pure and Mixture Adsorption Isothermsmentioning

confidence: 99%

Monte Carlo Simulation Strategies for Predicting CO₂/CH₄ Adsorption onto Activated Carbons from Pure Gas Isotherms

Oliveira

Rios

López

et al. 2011

Adsorption Science & Technology

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ABSTRACT:The problem of predicting the adsorptive properties of activated carbon (AC) towards a mixture of gases from the simple knowledge of the adsorption properties of the pure components is addressed, with special reference to the CO 2 /CH 4 mixture. The adsorption process for the pure gases and their mixtures was simulated using the Grand Canonical Monte Carlo (GCMC) method and the calculations were then used to analyze experimental isotherms for the pure gases and for mixtures with different molar fractions in the gaseous phase. It was shown that the pore-size distributions (PSDs) "sensed" by each of the pure probe gases was different one from the other and also from the PSDs "seen" by the mixture. A mixing rule for combining the PSDs corresponding to the pure gases is proposed for obtaining predictions regarding the adsorption of the corresponding mixtures, which are then compared with those arising from the classical IAST approximation. For this purpose, selectivity curves for CO 2 relative to CH 4 have been calculated and compared with experimental values. It was concluded that, for the adsorbate/adsorbent system under study, the proposed GCMC mixed model was capable of predicting the binary adsorption equilibrium, and especially the selectivity, more accurately than the IAST.

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“…In porous membranes, the pore flow model describes pervaporation as liquid permeation under a pressure difference, such as the Hagen–Poiseuille (HP) equation. − Most of these conventional models tend to describe the flow behavior based on the assumption of homogeneous fluids ,, and using their bulk properties. However, the fluid is inhomogeneous when confined within nanometer or subnanometer spaces (<2 nm), and their properties, such as density, diffusion coefficient, and viscosity, significantly differ from those observed in bulk phases when confined within nanometer or subnanometer spaces (<2 nm). − This is because, according to the molecular collision theory, the interaction between fluids and solids cannot be ignored for the fluids passing through 2D nanochannels. , For example, early studies have mentioned the classical coupling effects of two phenomena during the multicomponent pervaporation process, i.e., the coupling of flow and thermodynamic interactions leads to preferential adsorption . Experimentally, the measurements of attenuated total reflection (ATR) infrared spectroscopy, atomic force microscopy (AFM), and scanning tunneling microscopy (STM) also revealed an ice-like structure of the water molecules near the surface.…”

Section: Introductionmentioning

confidence: 99%

Modeling of Alcohol/Water Separation in Graphene-Based Membranes: The Roles of Interfacial Adsorption and the Effective Transfer Path

Pan,

Ma,

Qin

et al. 2024

Ind. Eng. Chem. Res.

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With the expansion of the modern chemical industry into the nanoscale, two-dimensional (2D) graphene-based membranes have gained significant attention in alcohol/water mixture separation due to their large lateral dimensions and nanometer thickness. However, the interface-induced effect is poorly explained for a further understanding of the confined transfer mechanism of mixed fluids through 2D nanochannels. In this work, we proposed a theoretical framework considering the interfacial adsorption effect and effective transfer path of mixed fluids to describe the selectivity accurately of different alcohol/water systems (ethanol/water, n-butanol/water, and isopropanol/water) in 2D graphene-based membranes. Our results demonstrated that the low friction resistance of water contributed to the high permeation of water and the high selectivity of water/alcohol. Finally, we also discovered that there was a beneficial permeation for alcohol rather than water within a certain range of slit widths in the graphene channel, and the different slit widths for the graphene and MXene channels would have their specific separation performance for ethanol/water mixture due to the change of wettability and confined degree.

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On the influence of heterogeneity of graphene sheets in the determination of the pore size distribution of activated carbons

Cited by 21 publications

References 20 publications

Prediction of chlorophenols adsorption on activated carbons by representative pores method

Prediction of chlorophenols adsorption on activated carbons by representative pores method

Monte Carlo Simulation Strategies for Predicting CO₂/CH₄ Adsorption onto Activated Carbons from Pure Gas Isotherms

Modeling of Alcohol/Water Separation in Graphene-Based Membranes: The Roles of Interfacial Adsorption and the Effective Transfer Path

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On the influence of heterogeneity of graphene sheets in the determination of the pore size distribution of activated carbons

Cited by 21 publications

References 20 publications

Prediction of chlorophenols adsorption on activated carbons by representative pores method

Prediction of chlorophenols adsorption on activated carbons by representative pores method

Monte Carlo Simulation Strategies for Predicting CO2/CH4 Adsorption onto Activated Carbons from Pure Gas Isotherms

Modeling of Alcohol/Water Separation in Graphene-Based Membranes: The Roles of Interfacial Adsorption and the Effective Transfer Path

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Product

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Monte Carlo Simulation Strategies for Predicting CO₂/CH₄ Adsorption onto Activated Carbons from Pure Gas Isotherms