Abstract

In the future energy scenario, production of hydrogen is a promising solution for the storage of renewables.Photoelectrochemical water splitting with integrated devices can be engaged for the production of hydrogen with theadvantage of less space consumption and saving power lines to the production site. Current devices have alreadycome close to the efficiency of an electrolyzer coupled to a solar cell [1]. However, to be profitable in commercial useseveral challenges have to be resolved. One of the most pressing issues is photostability of materials during operation.Even so photoelectrodes are able to reach lifetimes of several days in lab conditions, it is still a long way until realdevice lifespans of several years are possible.While efforts in the field of photoelectrochemical water splitting is mainly focused on achieving higher activity, researchon stability is still at the very beginning. Evaluation of photostability is typically done by rather short (only few hours)chronoamperometry measurements and post mortem analysis. One option to study degradation processes in-situ is touse on-line inductively coupled plasma mass spectrometry (on-line ICP-MS) which became available recently andrevealed photocorrosion of WO3 [2] and BiVO4 [3].In this study, we aim to achieve a better understanding of the key factors driving photocorrosion. It has already beenshown, that WO3 exhibits significant differences in faradaic efficiency towards the oxygen evolution reaction (OER) invarious electrolytes [4]. One reason behind this behavior might be degradation processes driven by the electrolyte. Tostudy the effect of electrolytes on stability, dissolution of spray-coated WO3 films was investigated in four electrolytes(HClO4, H2SO4, HNO3 and CH3SO3H). Additionally, the influence of protective iridium co-catalyst layers on stability,synthesized in various thicknesses by atomic layer deposition (ALD) was explored.1. Cheng, W.-H., et al., Monolithic Photoelectrochemical Device for Direct Water Splitting with 19% Efficiency. ACSEnergy Letters, 2018. 3(8): p. 1795-1800.2. Knöppel, J., et al., Time-resolved analysis of dissolution phenomena in photoelectrochemistry – A case study ofWO3 photocorrosion. Electrochemistry Communications, 2018. 96: p. 53-56.3. Zhang, S., et al., Dissolution of BiVO4 Photoanodes Revealed by Time-Resolved Measurements UnderPhotoelectrochemical Conditions. The Journal of Physical Chemistry C, 2019.4. Reinhard, S., F. Rechberger, and M. Niederberger, Commercially Available WO3 Nanopowders forPhotoelectrochemical Water Splitting: Photocurrent versus Oxygen Evolution. ChemPlusChem, 2016. 81: p.935-940.

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