2024 article

3D-Printed Hydrogel Filter for Biocatalytic CO<sub>2</sub> Capture

Zhang, S., Shen, J., Zhang, P., Schroeder, T. B. H., Chen, J., Carnevale, C., … Fang, X. (2024, July 22). ADVANCED MATERIALS TECHNOLOGIES.

By: S. Zhang n, J. Shen n, P. Zhang n, T. Schroeder n, J. Chen n, C. Carnevale n, S. Salmon n, X. Fang n

author keywords: additive manufacturing; gas-liquid contactors; interpenetrating polymer network hydrogel
UN Sustainable Development Goal Categories
13. Climate Action (OpenAlex)
Source: Web Of Science
Added: August 5, 2024

Abstract Innovative scalable CO 2 capture technologies are urgently needed to combat the climate crisis. Reactive absorption in alkaline liquids, an essential process for capturing CO 2 at atmospheric pressure, requires high gas–liquid contact and fast reaction kinetics. To meet these needs, self‐supporting hydrogel CO 2 gas–liquid contactors (or simply “CO 2 filters”) containing the CO 2 selective catalyst carbonic anhydrase (CA) are developed using the direct ink writing additive manufacturing approach. The multifunctional filters are composed of semi‐interpenetrating polymer network hydrogels (IPNHs) of poly (ethylene glycol) diacrylate/poly (ethylene oxide) (PEG‐DA/PEO) upon photocuring during 3D printing. Formulations with PEG‐DA levels of 30–60 wt% are sufficiently homogeneous and reactive to produce coherent grids. Based on operational parameters, a 56 wt% PEG‐DA formulation is selected to continuously print self‐supporting 3D stacked cylindrical grids, with or without enzymes in ink. The resulting enzyme‐laden IPHN filters deliver ≈3 times higher CO 2 capture efficiency than the no‐enzyme control filters in a laboratory‐scale absorption column test. However, the enhancement effect decreases significantly within 2 d of operation, likely due to burst release of enzymes caused by the flowing solution. Covalent crosslinking of CA near the surface, which can improve durability and CO 2 capture performance, will be evaluated in future studies.