Wiesner, Florian ; Limper, Alexander ; Marth, Cedric ; Brodersen, Anselm ; Wessling, Matthias ; Linkhorst, John (2023)
Additive manufacturing of intertwined electrode pairs - guided mass transport with gyroids.
In: Advanced Engineering Materials, 25 (1)
doi: 10.1002/adem.202200986
Article, Bibliographie
Abstract
Electrochemical flow reactors facilitate the storage of renewable energies and the carbon-neutral production of platform chemicals. To maximize the reactor efficiency, unhindered mass transport in the flow channel and high surface electrodes is required. However, state-of-the-art reactors are limited by the conventional parallel plate designs. Herein, 3D intertwined electrode pairs are presented, based on triply periodic minimal surfaces that facilitate mass transport and provide high surface areas. Three gyroid designs with outer dimensions of 20 × 40 × 70 mm are manufactured from stainless steel via selective laser melting and implemented into a conventional flow cell. By design, the electrodes are rendered porous through the targeted control of the energy density during fabrication. Mass transport characterization by use of the fast ferri-/ferrocyanide redox reaction demonstrates that smaller unit cells and thus shorter interelectrode distances achieve significantly increased current densities. Moreover, the addition of convective channels formed by second-level gyroid structures removes diffusion boundary layers by promoting convective flow in electrode vicinity. The convective flow enhancement of the microscale channels even surpasses the effect of the unit cell size reduction, demonstrating importance of mass transport control. The integrated electrode design holds great potential for efficient next-generation electrochemical flow reactors.
Item Type: | Article |
---|---|
Erschienen: | 2023 |
Creators: | Wiesner, Florian ; Limper, Alexander ; Marth, Cedric ; Brodersen, Anselm ; Wessling, Matthias ; Linkhorst, John |
Type of entry: | Bibliographie |
Title: | Additive manufacturing of intertwined electrode pairs - guided mass transport with gyroids |
Language: | English |
Date: | 2023 |
Publisher: | Wiley |
Journal or Publication Title: | Advanced Engineering Materials |
Volume of the journal: | 25 |
Issue Number: | 1 |
DOI: | 10.1002/adem.202200986 |
Abstract: | Electrochemical flow reactors facilitate the storage of renewable energies and the carbon-neutral production of platform chemicals. To maximize the reactor efficiency, unhindered mass transport in the flow channel and high surface electrodes is required. However, state-of-the-art reactors are limited by the conventional parallel plate designs. Herein, 3D intertwined electrode pairs are presented, based on triply periodic minimal surfaces that facilitate mass transport and provide high surface areas. Three gyroid designs with outer dimensions of 20 × 40 × 70 mm are manufactured from stainless steel via selective laser melting and implemented into a conventional flow cell. By design, the electrodes are rendered porous through the targeted control of the energy density during fabrication. Mass transport characterization by use of the fast ferri-/ferrocyanide redox reaction demonstrates that smaller unit cells and thus shorter interelectrode distances achieve significantly increased current densities. Moreover, the addition of convective channels formed by second-level gyroid structures removes diffusion boundary layers by promoting convective flow in electrode vicinity. The convective flow enhancement of the microscale channels even surpasses the effect of the unit cell size reduction, demonstrating importance of mass transport control. The integrated electrode design holds great potential for efficient next-generation electrochemical flow reactors. |
Uncontrolled Keywords: | additive manufacturing, electrochemical flow reactor, gyroid,paired electrode design, triply periodic minimal surface |
Divisions: | 16 Department of Mechanical Engineering 16 Department of Mechanical Engineering > Chair for Process Engineering of Electrochemical Systems |
Date Deposited: | 13 Sep 2023 11:13 |
Last Modified: | 24 Jul 2024 08:23 |
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