Development of a fluorophilic ion-exchange material with dual binding mechanism for solid-phase extraction of PFAS

Freilinger, Johanna; Back, Jan O.; Plangger, Raphael; Schottenberger, Herwig; Huck, Christian W.; Rupprich, Marco; Bakry, Rania

Development of a fluorophilic ion-exchange material with dual binding mechanism for solid-phase extraction of PFAS

Files

1-s2.0-S2666911025000188-main.pdf(2.26 MB)

Authors

Freilinger, Johanna

Back, Jan O.

Plangger, Raphael

Schottenberger, Herwig

Huck, Christian W.

Rupprich, Marco

Bakry, Rania

Author (Corporation)

Publication date

11.2025

Type of student thesis

Course of study

Collections

Institute for Ecopreneurship

Full item page

Type

01A - Journal article

Editors

Editor (Corporation)

Supervisor

Parent work

Journal of Hazardous Materials Letters

Special issue

DOI of the original publication

https://doi.org/10.1016/j.hazl.2025.100158

URI

https://irf.fhnw.ch/handle/11654/55474
https://doi.org/10.26041/fhnw-15308

Link

Series

Series number

Volume

6

Issue / Number

Pages / Duration

100158

Patent number

Publisher / Publishing institution

Elsevier

Place of publication / Event location

Edition

Version

Programming language

Assignee

Practice partner / Client

Abstract

Per- and polyfluoroalkyl substances (PFAS) are persistent contaminants for which authorities worldwide have imposed limits on drinking water, groundwater and surface water. This has created challenges in PFAS detection, leading to an urgent need for reliable and selective solid-phase extraction (SPE) materials for PFAS analysis. In addressing this demand, we have tailored highly crosslinked copolymers containing 3-(1H,1H,2H,2H-perfluorooctyl)-1-vinylimidazolium chloride as a comonomer with ethylene dimethacrylate in various molar ratios. For ionic fluorosurfactants, these copolymers feature a dual binding mechanism that synergistically combines fluorophilic interactions and electrostatic attraction, enhancing selectivity and efficiency. The adsorption behavior of short- and long-chain PFAS and their recoveries were evaluated and compared to commercial SPE cartridges. Characterization revealed the highest ion-exchange capacity (412.7 ± 22 µeq g−1) for a monomer-to-crosslinker ratio of 2:1. The dynamic adsorption capacities for various PFAS ranged from 15.2 to 306 g−1. Recovery experiments consistently demonstrated high PFAS recoveries (98.8–121.6 %), while enrichment studies from wastewater confirmed its robustness in complex environmental matrices (recoveries: 90.8–99.2 %). Additionally, reusability experiments showed consistent recoveries over five cycles (recoveries: 90.34–108.0 %). The findings underscore the potential of this innovative polyelectrolyte as a selective, regenerable, and efficient alternative to conventional SPE materials, qualifying it as a superior candidate for PFAS analysis.

Keywords

PFAS, Solid-phase extraction, Fluorophilic polymer, Adsorption, Environmental analysis, Ion exchange

Subject (DDC)

600 - Technik, Medizin, angewandte Wissenschaften

Project

Event

Exhibition start date

Exhibition end date

Conference start date

Conference end date

Date of the last check

ISBN

ISSN

2666-9110

Language

English

Created during FHNW affiliation

Yes

Strategic action fields FHNW

Zero Emission

Publication status

Published

Review

Peer review of the complete publication

Open access category

Gold

License

Citation

Freilinger, J., Back, J. O., Plangger, R., Schottenberger, H., Huck, C. W., Rupprich, M., & Bakry, R. (2025). Development of a fluorophilic ion-exchange material with dual binding mechanism for solid-phase extraction of PFAS. Journal of Hazardous Materials Letters, 6, 100158. https://doi.org/10.1016/j.hazl.2025.100158

Full item page