A branched pore kinetic model for activated carbon adsorption

Peel, Russell G.; Benedek, Andrew; Crowe, C. M.

doi:10.1002/aic.690270106

Cited by 142 publications

(59 citation statements)

References 20 publications

(19 reference statements)

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“…Homogeneous solid surface diffusion models have been developed for the adsorption of phenol onto activated carbon using the Crank-Nickolson ® nite difference method to solve the diffusion equation 53 , the adsorption of phenolic compounds onto carbon using orthogonal collocation to solve the diffusion equation 54 and the adsorption of basic dyes onto silica 55 and basic dyes onto activated carbon 56 , using a semi-analytical solution to solve the diffusion equation. Branched pore diffusion models based on macro-, meso-and micropore diffusion have been developed for phenol adsorption 57 and dye adsorption on activated carbon 58 . The application of variable surface diffusivity to the HSDM has been studied in several cases 59 61 .…”

Section: Analysis Of Data From the Literaturementioning

confidence: 99%

A Comparison of Chemisorption Kinetic Models Applied to Pollutant Removal on Various Sorbents

McKay

1998

Process Safety and Environmental Protection

2,027

898

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A comparison of kinetic models describing the sorption of pollutants has been reviewed. The rate models evaluated include the Elovich equation, the pseudo-® rst order equation and the pseudo-second order equation. Results show that chemisorption processes could be rate limiting in the sorption step. The pseudo-second order equation may be applied for chemisorption processes with a high degree of correlation in several literature cases where a pseudo-® rst order rate mechanism has been arbitrarily assumed.

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Section: Analysis Of Data From the Literaturementioning

confidence: 99%

A Comparison of Chemisorption Kinetic Models Applied to Pollutant Removal on Various Sorbents

McKay

1998

Process Safety and Environmental Protection

2,027

898

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“…Transfer rate of solute from macropore to micropore: (Peel et al, 1981;Yang and Al-Duri, 2001;Ko et al, 2002) Shrinking core theory model This model used to describe the intrapellet adsorption is controlled by pore diffusion, supposing adsorption firstly occurs at the outer region of adsorbent, then the mass transfer zone moves inward together with the extending of saturated outer region and shrinking of unloaded core (Fig. 5) The mass transfer flux at the solid-liquid phase interface: Du et al, 2007;2008) To be continued A review of surface diffusion is available elsewhere (Medved and Cerny, 2011), which might provide some ideas to modify the intrapellet diffusion models.…”

Section: General Rate Modelsmentioning

confidence: 99%

Mathematically modeling fixed-bed adsorption in aqueous systems

Cai

Pan

2013

J. Zhejiang Univ. Sci. A

325

166

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Adsorption is one of the widely used processes in the chemical industry environmental application. As compared to mathematical models proposed to describe batch adsorption in terms of isotherm and kinetic behavior, insufficient models are available to describe and predict fixed-bed or column adsorption, though the latter one is the main option in practical application. The present review first provides a brief summary on basic concepts and mathematic models to describe the mass transfer and isotherm behavior of batch adsorption, which dominate the column adsorption behavior in nature. Afterwards, the widely used models developed to predict the breakthrough curve, i.e., the general rate models, linear driving force (LDF) model, wave propagation theory model, constant pattern model, Clark model, Thomas model, Bohart-Adams model, Yoon-Nelson model, Wang model, Wolborska model, and modified dose-response model, are briefly introduced from the mechanism and mathematical viewpoint. Their basic characteristics, including the advantages and inherit shortcomings, are also discussed. This review could help those interested in column adsorption to reasonably choose or develop an accurate and convenient model for their study and practical application.

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“…Study of pore size heterogeneity revealed the variation of adsorbate diffusivity within the porous adsorbent [23,39,40]. These processes have been modelled as a fractal-like dependence of diffusion coefficient [34,41,42], or to involve correlated variables, by categorising the adsorption kinetics into macropore and micropore diffusional regions, respectively [32,39,43]. As a key element for assessing the adsorption performance, the importance of surface diffusion in contributing to the total adsorbent mass transfer in porous materials has been highlighted in many liquid-surface adsorption systems [44,45].…”

Section: Introductionmentioning

confidence: 99%

Adsorption of pyridine from aqueous solutions by polymeric adsorbents MN 200 and MN 500. Part 2: Kinetics and diffusion analysis

Zhu

Moggridge

D’Agostino

2016

Chemical Engineering Journal

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Telephone: +44 (0)1223 334763Fax: +44 (0)1223 334796 2 AbstractThe adsorption kinetics of pyridine adsorption on Macronet adsorbents MN 200 and MN 500 from aqueous solution was investigated at various initial pyridine concentrations and temperatures. The Weber-Morris plots revealed the influence of both external film diffusion and intraparticle diffusion resistances. The two linear regions in Weber-Morris plots were attributed to macropore and micropore diffusion, which was associated to the bimodal pore size distribution of the adsorbents. New insights into the diffusion mechanisms were highlighted, with the proposed internal film diffusion resistance dominating into the macropore region, whereas homogeneous particle diffusion resistance describes diffusion in the micropore region. The importance of pore and surface diffusion in the micropores was noted in contributing to the observed diffusion kinetics. The pore diffusion coefficient was estimated from PFG (pulsedfield gradient) parameter and molecular diffusion coefficient of pyridine in bulk liquid. A greater contribution of the surface to the overall diffusion kinetics was found for MN 500 as inferred from a proposed calculation method, which agrees with its better adsorption performance. The overall findings highlight the effect of pore structure onto the diffusion mechanisms inside the pores and help to gain a better understanding into the adsorption kinetics of these Macronet adsorbents, which are promising materials for the removal of Nheterocyclic compounds from waste water.

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A branched pore kinetic model for activated carbon adsorption

Cited by 142 publications

References 20 publications

A Comparison of Chemisorption Kinetic Models Applied to Pollutant Removal on Various Sorbents

A Comparison of Chemisorption Kinetic Models Applied to Pollutant Removal on Various Sorbents

Mathematically modeling fixed-bed adsorption in aqueous systems

Adsorption of pyridine from aqueous solutions by polymeric adsorbents MN 200 and MN 500. Part 2: Kinetics and diffusion analysis

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