4.8 Article

Catalytic open-circuit passivation by thin metal oxide films of p-Si anodes in aqueous alkaline electrolytes

Journal

ENERGY & ENVIRONMENTAL SCIENCE
Volume 15, Issue 1, Pages 334-345

Publisher

ROYAL SOC CHEMISTRY
DOI: 10.1039/d1ee03040j

Keywords

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Funding

  1. Office of Science of the U.S. Department of Energy (DOE) [DE-SC0004993]
  2. DOE [DE-SC0022087]
  3. U.S. Department of Energy (DOE) [DE-SC0022087] Funding Source: U.S. Department of Energy (DOE)

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Research shows that Ni and NiOx-based thin films can catalyze the oxidation of Si in the presence of oxygen, extending the lifespan of Si/Ni electrodes. In contrast, electrodes without these films are more prone to corrosion. Operating in alkaline conditions, lowering the electrolyte pH can increase the durability of the photoanode, but may reduce the efficiency of water oxidation.
Ni and NiOx-based protective thin films are shown to catalyze the oxidation of Si in the presence of O-2 in strongly alkaline KOH(aq) even in the absence of illumination. The O-2 in solution drove the open-circuit potential of the electrode to >0.4 V, which is positive of the Si passivation potential. The elevated electrochemical potential of the surface promoted formation of passive oxides on exposed Si regions of Si/Ni electrodes. Catalytic passivation of Si extended the durability of an np(+)-Si(100)/NiOx photoanode to >400 h while operating under simulated day/night cycles. In contrast, electrodes without a Ni(O-x) layer and/or without O-2 in solution displayed direct etching of the Si and corrosion pitting during non-illuminated, simulated nighttime episodes of day/night cycling. The O-2-derived catalyzed passivation of Si using thin films can be generalized to multiple phases of NiOx as well as to materials other than Ni. Relative to operation in aqueous alkaline conditions, decreasing the pH of the electrolyte decreased the dissolution rate of the protective oxide layer formed by the catalyzed passivation process, and consequently increased the durability of the photoanode, but yielded lower photoelectrode fill factors for water oxidation due to the relatively large kinetic overpotentials for the electrocatalyzed oxygen-evolution reaction at near-neutral pH.

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