Triply periodic minimal surfaces as additive manufactured metal electrodes: Assessment through a hydrodynamic electrode performance factor
Triply periodic minimal surfaces as additive manufactured metal electrodes: Assessment through a hydrodynamic electrode performance factor
This work applies a hydrodynamic electrode performance factor (HEPF) to evaluate triply periodic minimal surface (TPMS) porous electrodes in electrochemical flow reactors. Traditional approaches to electrode characterization and optimization treat mass transfer and pressure drop as separate metrics, complicating comparisons. To address this, these parameters are integrated into a unified mathematical expression inspired by established heat transfer equations and the Chilton–Colburn analogy. The HEPF provides an alternative method to assess electrode performance, complementing the volumetric mass transfer coefficient, and Storck's energetic effectiveness principle for electrochemical reactors. Stainless steel 316 L TPMS electrodes with 60% target porosity are fabricated using additive manufacturing, their mass transfer and pressure drop analyzed experimentally. Mass transfer is determined from single-pass ferricyanide ion reduction rates measured using UV-vis spectroscopy. Pressure drop is measured directly across electrodes at various flow rates. Results demonstrated that TPMS structures, particularly the Schwarz-D, can achieve superior performance as porous electrodes by combining high surface area and mass transfer with low pressure drop. This study highlights the significance of integrating performance factors in electrode design, featuring the HEPF as a viable method for optimizing advanced electrodes for industrial applications.
TPMS, additive manufacturing, electrochemical engineering, mass transport, pressure drop, pumping power, structured electrode
Rop, Michiel De
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Arenas, Luis F.
6e7e3d10-2aab-4fc3-a6d4-63a6614d0403
Jacops, Robbe
6aeee4b4-96ed-451a-814c-826598f8af14
Breugelmans, Tom
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Hereijgers, Jonas
30f0d757-dbcb-4a69-8c73-716688046b66
21 August 2025
Rop, Michiel De
fcb0b95f-7e76-497f-925d-4121056d50ba
Arenas, Luis F.
6e7e3d10-2aab-4fc3-a6d4-63a6614d0403
Jacops, Robbe
6aeee4b4-96ed-451a-814c-826598f8af14
Breugelmans, Tom
f2506208-1ffe-41a6-bb45-a86b1d4f9d2d
Hereijgers, Jonas
30f0d757-dbcb-4a69-8c73-716688046b66
Rop, Michiel De, Arenas, Luis F., Jacops, Robbe, Breugelmans, Tom and Hereijgers, Jonas
(2025)
Triply periodic minimal surfaces as additive manufactured metal electrodes: Assessment through a hydrodynamic electrode performance factor.
ChemElectroChem, 12 (16), [e202500113].
(doi:10.1002/celc.202500113).
Abstract
This work applies a hydrodynamic electrode performance factor (HEPF) to evaluate triply periodic minimal surface (TPMS) porous electrodes in electrochemical flow reactors. Traditional approaches to electrode characterization and optimization treat mass transfer and pressure drop as separate metrics, complicating comparisons. To address this, these parameters are integrated into a unified mathematical expression inspired by established heat transfer equations and the Chilton–Colburn analogy. The HEPF provides an alternative method to assess electrode performance, complementing the volumetric mass transfer coefficient, and Storck's energetic effectiveness principle for electrochemical reactors. Stainless steel 316 L TPMS electrodes with 60% target porosity are fabricated using additive manufacturing, their mass transfer and pressure drop analyzed experimentally. Mass transfer is determined from single-pass ferricyanide ion reduction rates measured using UV-vis spectroscopy. Pressure drop is measured directly across electrodes at various flow rates. Results demonstrated that TPMS structures, particularly the Schwarz-D, can achieve superior performance as porous electrodes by combining high surface area and mass transfer with low pressure drop. This study highlights the significance of integrating performance factors in electrode design, featuring the HEPF as a viable method for optimizing advanced electrodes for industrial applications.
Text
ChemElectroChem - 2025 - De Rop - Triply Periodic Minimal Surfaces as Additive Manufactured Metal Electrodes Assessment (1)
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e-pub ahead of print date: 9 July 2025
Published date: 21 August 2025
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Publisher Copyright:
© 2025 The Author(s). ChemElectroChem published by Wiley-VCH GmbH.
Keywords:
TPMS, additive manufacturing, electrochemical engineering, mass transport, pressure drop, pumping power, structured electrode
Identifiers
Local EPrints ID: 508466
URI: http://eprints.soton.ac.uk/id/eprint/508466
ISSN: 2196-0216
PURE UUID: 26f45f2f-09dc-4a43-a5fa-97afd7836e8c
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Date deposited: 22 Jan 2026 17:45
Last modified: 23 Jan 2026 02:52
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Contributors
Author:
Michiel De Rop
Author:
Robbe Jacops
Author:
Tom Breugelmans
Author:
Jonas Hereijgers
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