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Abstract
Electrolysis research is typically conducted using commercially available cells with standard designs that are difficult to modify or custom-machined parts that are time-consuming to produce. Herein, we describe a method to rapidly produce lab-scale electrolysis cells that uses high-resolution, high-fidelity stereolithography 3D printing combined with electroless metal plating. Cells prepared by the printing/electroless plating method were compared to the same cells machined in Ti for CO electrolysis experiments. The printed cells showed very similar performance to the machined cells across a wide current density range (up to 250 mA cm-2) and demonstrated 24 h of stable operation in a zero-gap configuration. This work demonstrates the ability to prototype electrochemical cell designs in a fraction of the time required using conventional machining.
Supplementary materials
Title
Supplementary Information
Description
Materials; Detailed printing and electroless plating methods; full depth profiles of flow fields; pictures of plated electrode blocks; Ni electroplating procedure; experimental details; full cell potentials and SPCE data for flow cell experiments; impedance spectra; calculations.
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Title
Cathode Block .STL
Description
.STL file for 3D printing the cathode block in this study
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Anode Block .STL
Description
.STL file for 3D printing the anode block in this study
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Title
Electrolyte Compartment .STL
Description
.STL file for 3D printing the electrolyte compartment in this study
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