RESUMO
Development of a solar water splitting device requires design of a low-cost, efficient, and non-noble metal compound as alternative to noble metals. For the first time, we showed that CoSe2 can function as co-catalyst in phototoelectrochemical hydrogen production. We designed a heterostructure of p-Si and marcasite-type CoSe2 for solar-driven hydrogen production. CoSe2 successively coupled with p-Si can act as a superior photocathode in the solar-driven water splitting reaction. Photocurrents up to 9â mA cm(-2) were achieved at 0â V vs. reversible hydrogen electrode. Electrochemical impedance spectroscopy showed that the high photocurrents can be attributed to low charge transfer resistance between the Si and CoSe2 interfaces and that between the CoSe2 and electrolyte interfaces. Our results suggest that this CoSe2 is a promising alternative co-catalyst for hydrogen evolution.
RESUMO
We prepared Ag-Si microflowers as the photocathode for water splitting through a facile chemical method. The photocurrent and the hydrogen evolution rate of partially Ag particle decorated-Si microwires were enhanced through the synergistic effects of Ag co-catalytic and plasmonic assistance.