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DOI: 10.4121/8aae7661-4af1-4604-9653-8ea10eed0afd

Dykstra, Jouke; Li, Kaiyue; Geranikolahlooei, Hanieh; Rutten, Sam; Nordstrand, Johan et. al. (2025): Data underlying the publication: Pushing the boundaries of electrochemical ion separation for near-identical ions. Version 1. 4TU.ResearchData. dataset. https://doi.org/10.4121/8aae7661-4af1-4604-9653-8ea10eed0afd.v1

Categories

• Environmental Engineering
• Chemical Engineering
• Engineering

Keywords

Capacitive deionization Concentration dependent switching Electrochemical separation Electrosorption Ion-ion selectivities

Licence

CC BY 4.0

Interoperability

• RO-Crate Metadata

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by Jouke Dykstra , Kaiyue Li , Hanieh Geranikolahlooei, Sam Rutten, Johan Nordstrand , Slawomir Porada

In recent decades, increasing global population and industrialization have driven interest in the sustainable extraction of valuable resources from water, as well as in water reuse applications. This includes selectively removing undesired ions, such as sodium, or extracting valuable ions, such as lithium, from water. These separations are difficult to achieve due to the high concentrations of competing ions with similar properties, such as charge and size. As a result, separating similar ions, e.g., sodium, potassium, and lithium, is often regarded as the ‘holy grail’ of ion separation. Although selective separation can be achieved with electrochemical desalination technologies, the limited selectivity for ions with the same charge is insufficient for many applications. In the publication, we introduce a novel approach for achieving exceptionally high selectivity between two very similar ions, sodium and potassium, by adapting switching times of ion collection. We demonstrate that our method, termed Concentration Dependent Switching (CDS), is effective for sodium and potassium, achieving high removal of one ion while leaving the other in solution. The high removal can be achieved to either of the ions in solution. We highlight its applicability to other challenging separations, including lithium and sodium. The CDS method can be integrated into any cyclically operated deionization technology that exhibits differences in the dynamics of adsorption and desorption of ions. This datafile contains the experimental data, the output of our models and the model files.

History

• 2025-11-03 first online, published, posted

Publisher

4TU.ResearchData

Format

spreadsheet/.xlsx; script/.m; script/.mph

Associated peer-reviewed publication

Pushing the boundaries of electrochemical ion separation for near-identical ions

Organizations

Environmental Technology, Wageningen University & Research
Wetsus, European Centre of Excellence for Sustainable Water Technology
Laboratory of Organic Chemistry, Wageningen University & Research
Department of Chemistry, Stanford University
Process Engineering and Technology of Polymeric and Carbon Materials, Wroclaw University of Science and Technology