Issue 20, 2022

The effect of water ingress on additively manufactured electrodes

Abstract

Additive Manufacturing (AM), otherwise known as 3D printing, is becoming increasingly popular in the field of electrochemistry since it allows affordable, on-demand production of bespoke devices. Provided a suitably conductive polymer composite material is used, this can include working electrodes. However, while a number of publications have shown such Additively Manufactured Electrodes (AMEs) to be effective, there remain several fundamental areas which must be understood to continue the development of AM for electrochemistry. One such area is the effect of solvent ingress on AME performance, with water probably representing the most important solvent for study considering the amount of electrochemical sensing directed towards biological and environmental systems. Therefore, in this work we study the effect of up to 28 days of water immersion on the physical properties and electrochemical performance of AMEs made from a commonly used conductive material, Protopasta. It is shown that water immersion leads to water uptake of around 1–1.5% by mass for our specific electrode design, which in turn causes a decrease in measured peak current, but an increase in the heterogeneous electron transfer rate constant, k0. These observations are rationalised in terms of Ohmic drop and conductive filler surface chemistry, respectively. Overall, it can be concluded that water ingress is likely to be a concern for any application where AMEs are expected to have extended contact with water, although we note that more work is required to fully understand the extent of the issue.

Graphical abstract: The effect of water ingress on additively manufactured electrodes

Supplementary files

Article information

Article type
Paper
Submitted
18 jun 2022
Accepted
08 ago 2022
First published
08 ago 2022
This article is Open Access
Creative Commons BY license

Mater. Adv., 2022,3, 7632-7639

The effect of water ingress on additively manufactured electrodes

R. J. Williams, T. Brine, R. D. Crapnell, A. G. Ferrari and C. E. Banks, Mater. Adv., 2022, 3, 7632 DOI: 10.1039/D2MA00707J

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