Mass transfer enhancement in electrochemical flow cells through 3D-printed biomimetic channels
Mass transfer enhancement in electrochemical flow cells through 3D-printed biomimetic channels
Mass transfer is frequently the rate-limiting step in electrochemical processes. In addition to increasing electrolyte flow rate, transfer limitations in electrochemical flow cells can be mitigated by inducing turbulence in the flow fields. This can be achieved by substituting the conventional rectangular channel cell design for flow fields that promote chaotic movement in the electrolyte. In this work, a novel biomimetic channel concept based on space-filling curves created by differential growth, such as those present in rippled surfaces of plants and river meanders, is proposed. The overall performance was analyzed in an undivided flow cell by the limiting current technique as a function of electrolyte flow rate. The performance of the biomimetic flow field is enhanced on average by a factor of 1.9 and 1.1 with respect to the rectangular and serpentine flow fields, respectively. The designed flow field increased pressure drop in comparison to the other flow fields but at levels similar to the typical FM01-LC flow reactor with porous electrodes. Differential growth flow fields open a window to further application in inorganic and organic flow electrosynthesis at various scales, as this parametric design allows for channel adaption to the reaction requirements.
García-López, Inmaculada
92d9a7da-8e2a-49bf-87f2-5c587ccf510b
Arenas, Luis Fernando
6e7e3d10-2aab-4fc3-a6d4-63a6614d0403
Turek, Thomas
bb838761-36b5-47d2-aacd-08f1b9db38f3
Águeda, Vicente Ismael
4214c5c8-e259-455e-a162-4187aef1790a
Garrido-Escudero, Amalio
05591657-e905-477b-92b8-7daf871ad437
13 April 2023
García-López, Inmaculada
92d9a7da-8e2a-49bf-87f2-5c587ccf510b
Arenas, Luis Fernando
6e7e3d10-2aab-4fc3-a6d4-63a6614d0403
Turek, Thomas
bb838761-36b5-47d2-aacd-08f1b9db38f3
Águeda, Vicente Ismael
4214c5c8-e259-455e-a162-4187aef1790a
Garrido-Escudero, Amalio
05591657-e905-477b-92b8-7daf871ad437
García-López, Inmaculada, Arenas, Luis Fernando, Turek, Thomas, Águeda, Vicente Ismael and Garrido-Escudero, Amalio
(2023)
Mass transfer enhancement in electrochemical flow cells through 3D-printed biomimetic channels.
Reaction Chemistry & Engineering, 7.
(doi:10.1039/D3RE00053B).
Abstract
Mass transfer is frequently the rate-limiting step in electrochemical processes. In addition to increasing electrolyte flow rate, transfer limitations in electrochemical flow cells can be mitigated by inducing turbulence in the flow fields. This can be achieved by substituting the conventional rectangular channel cell design for flow fields that promote chaotic movement in the electrolyte. In this work, a novel biomimetic channel concept based on space-filling curves created by differential growth, such as those present in rippled surfaces of plants and river meanders, is proposed. The overall performance was analyzed in an undivided flow cell by the limiting current technique as a function of electrolyte flow rate. The performance of the biomimetic flow field is enhanced on average by a factor of 1.9 and 1.1 with respect to the rectangular and serpentine flow fields, respectively. The designed flow field increased pressure drop in comparison to the other flow fields but at levels similar to the typical FM01-LC flow reactor with porous electrodes. Differential growth flow fields open a window to further application in inorganic and organic flow electrosynthesis at various scales, as this parametric design allows for channel adaption to the reaction requirements.
This record has no associated files available for download.
More information
Published date: 13 April 2023
Identifiers
Local EPrints ID: 501975
URI: http://eprints.soton.ac.uk/id/eprint/501975
ISSN: 2058-9883
PURE UUID: 9ceaa0d8-affc-4dcf-988a-42f5fb66b702
Catalogue record
Date deposited: 12 Jun 2025 17:16
Last modified: 13 Jun 2025 01:55
Export record
Altmetrics
Contributors
Author:
Inmaculada García-López
Author:
Thomas Turek
Author:
Vicente Ismael Águeda
Author:
Amalio Garrido-Escudero
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
