Selective sodium removal with electrodialysis by modifying concentration gradients using EDTA complexation

•Electrodialysis combined with EDTA complexation is proposed to improve selective Na+ removal.•EDTA complexation can improve diffusion of Na+ while increasing back diffusion of K+.•Proposed process can enhance the selective removal of Na+ ions.•High pH, low applied voltage and high EDTA/Na+ ratio im...

Full description

Saved in:
Bibliographic Details
Published inSeparation and purification technology Vol. 337; p. 126337
Main Authors Ozkul, Selin, Scharfberg, Hadar, Bisselink, Roel J.M., Kuipers, Norbert J.M., Bruning, Harry, Rijnaarts, Huub H.M., Dykstra, Jouke E.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 13.06.2024
Subjects
Desalination
EDTA complexation
Electrodialysis
Ion transport
Selective diffusion
Sodium removal
Ion transport
EDTA complexation
Sodium removal
Selective diffusion
Desalination
Electrodialysis
Online AccessGet full text

Cover

More Information
Summary:•Electrodialysis combined with EDTA complexation is proposed to improve selective Na+ removal.•EDTA complexation can improve diffusion of Na+ while increasing back diffusion of K+.•Proposed process can enhance the selective removal of Na+ ions.•High pH, low applied voltage and high EDTA/Na+ ratio improve the process selectivity.•EDTA recovery of >95 % can be achieved by acidification at pH < 2 in 30 min. Circular water reuse is often limited by the accumulation of harmful ions and the loss of valuable ions during water desalination. Selective removal of specific ions from water is essential but challenging with conventional desalination technologies, especially for ions with similar properties, such as sodium (Na+) and potassium (K+). In the present study, the use of electrodialysis in combination with EDTA complexation in the concentrate is proposed to selectively remove Na+ ions from a multi-ionic solution containing Na+, K+, and NO3− ions. Electrodialysis experiments were conducted at lab-scale at different operational conditions (i.e. solution pH, applied voltage, EDTA/Na+ ratio and solution ion composition) to evaluate the selectivity of the proposed process. It was found that a high solution pH (>10) and a low applied voltage (<0.3 V per cell pair) is required to maximize the selective transport of Na+ ions, while the presence of other metal ions in solution limits the process efficiency. The effect of the proposed process on the transport mechanisms in electrodialysis, which are electromigration, convection and diffusion, was also examined. The provided analysis concluded that the electromigration and convection mechanisms show the largest contribution to the transport of both Na+ and K+ ions, while the process selectivity is controlled by selective diffusion of ions which is enhanced by EDTA complexation. Finally, the regeneration and recovery of EDTA with acidification was experimentally evaluated at different pH values and different precipitation times; recoveries of >95 % were achieved with an acidic solution with pH < 2 in 30 min.
ISSN:1383-5866
1873-3794
DOI:10.1016/j.seppur.2024.126337