Modelling ion exchange kinetics in zeolyte-type materials using Maxwell-Stefan approach

abstract

In this essay, the Maxwell-Stefan (MS) formalism was adopted to model the removal of cadmium(II) and mercury(II) ions from aqueous solutions using microporous titanosilicate ETS-4. The embodied transport mechanism is surface diffusion, since the small pore diameters of such zeolite-type materials imply that counter ions never escape from the force field of the matrix co-ions, mainly owing to the strong and long range electrostatic interactions. The parameters of the global model are the MS diffusivities of ion-ion and ion-solid pairs, and a convective mass transfer coefficient. The average absolute relative deviations (AARD) achieved for Cd2+/Na+/ETS-4 and Hg2+/Na+/ETS-4 systems were only 3.47 and 7.34%, respectively. The model calculates concentration profiles and their evolution along time under transient regime, being able to represent the initial steep branches of removal curves and subsequent transition to equilibrium, where kinetic curves are frequently very difficult to fit. The well-known and frequently used pseudo-first and pseudo-second-order equations were also chosen for comparison, and provided large deviations: AARD(Cd2+) = 48.9% and AARD(Hg2+) = 26.6 % (first order), and AARD(Cd2+) = 29.0% and AARD(Hg2+) = 54.6% (second order).

keywords

MICROPOROUS TITANOSILICATE ETS-10; AQUEOUS-SOLUTION; ELECTROLYSIS PROCESS; REMOVAL; DIFFUSION; EQUILIBRIUM; SORPTION; WASTEWATERS; EQUATIONS; WATERS

subject category

Engineering; Water Resources

authors

Lito, PF; Aniceto, JPS; Silva, CM

our authors

acknowledgements

P.F. Lito and J.P.S. Aniceto wish to thank the grants provided by Fundacao para a Ciencia e a Tecnologia (Portugal) (SFRH/BPD/63214/2009 and SFRH/BD/91231/2012). Authors thank Pest-C/CTM/LA0011/2011 for Associate Laboratory CICECO funding.

Share this project:

Related Publications

We use cookies for marketing activities and to offer you a better experience. By clicking “Accept Cookies” you agree with our cookie policy. Read about how we use cookies by clicking "Privacy and Cookie Policy".