Film–pore diffusion models—analytical and numerical solutions

The sorption of acid dyes from aqueous effluents onto activated carbon has been studied. The effects of initial dye concentration and activated carbon mass on the rate of Acid Blue 80 and Acid Yellow 117 removal have been investigated. Three mass transport models based on film and pore diffusion con...

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Veröffentlicht in:	Chemical engineering science 2004-02, Vol.59 (3), p.501-512
Hauptverfasser:	Choy, Keith K.H., Porter, John F., McKay, Gordon
Format:	Artikel
Sprache:	eng
Schlagworte:	Acid Blue 80 Acid Yellow 117 Activated carbon Analytical method Applied sciences Batch sorption Chemical engineering Exact sciences and technology Film-pore diffusion Miscellaneous Numerical method
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container_title	Chemical engineering science
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creator	Choy, Keith K.H. Porter, John F. McKay, Gordon
description	The sorption of acid dyes from aqueous effluents onto activated carbon has been studied. The effects of initial dye concentration and activated carbon mass on the rate of Acid Blue 80 and Acid Yellow 117 removal have been investigated. Three mass transport models based on film and pore diffusion control have been applied to model the experimental concentration decay curves. The models are compared on the basis of the solid-phase loading capacity using various assumptions since the assignment of an appropriate solid-phase loading has been the subject of several papers on this topic and no comparisons have been provided on the effectiveness of each approach. The equilibrium solid-phase concentration is assumed: (i) incorporating a time-dependent solid-phase concentration Y e, t , (ii) equal to the intersection point of the equilibrium isotherm and the operating line and (iii) the point on the equilibrium isotherm where the liquid-phase concentration equals the initial concentration in the film–pore diffusion model.
doi_str_mv	10.1016/j.ces.2003.10.012
format	Article
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subjects	Acid Blue 80 Acid Yellow 117 Activated carbon Analytical method Applied sciences Batch sorption Chemical engineering Exact sciences and technology Film-pore diffusion Miscellaneous Numerical method
title	Film–pore diffusion models—analytical and numerical solutions
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