Abstract
Photoelectrochemical (PEC) water splitting can be an efficient and economically feasible alternative for hydrogen production if easily processed photoelectrodes made of inexpensive and abundant materials are employed. Here, we present the preparation of porous Cu2O photocathodes with good PEC performance using solely inexpensive electrodeposition methods. Firstly, porous Cu structures with delicate pore networks were deposited on flat Cu substrates employing hydrogen-bubble-assisted Cu deposition. In a second electrodeposition step, the porous Cu structures were mechanically reinforced and subsequently detached from the substrates to obtain free-standing porous frameworks. In a third and final step, photoactive Cu2O films were electrodeposited. The PEC water splitting performance in 0.5 M Na2SO4 (pH ∼6) shows that these photocathodes have photocurrents of up to −2.25 mA cm−2 at 0 V versus RHE while maintaining a low dark current. In contrast, the Cu2O deposited on a flat Cu sample showed photocurrents only up to −1.25 mA cm−2. This performance increase results from the significantly higher reactive surface area while maintaining a thin and homogeneous Cu2O layer with small grain sizes and therefore higher hole concentrations as determined by Mott-Schottky analysis. The free-standing porous Cu2O samples show a direct optical transmittance of 23% (λ = 400–800 nm) and can therefore be used in tandem structures with a photoanode in full PEC cells.Graphical abstract
Highlights
Hydrogen is considered as a clean and sustainable energy carrier for the future but is, for economic reasons, currently mainly produced by steam reforming of fossil fuels [1]
An ultrasonication process separates the reinforced porous layer from the flat Cu substrate to form a stable freestanding porous Cu framework, which has tubular shaped through pores
A layer of Cu2O was electrodeposited in an alkaline copper bath on various porous and flat Cu substrates
Summary
Hydrogen is considered as a clean and sustainable energy carrier for the future but is, for economic reasons, currently mainly produced by steam reforming of fossil fuels [1]. To improve the surface morphology and the mechanical stability of the dendritic porous structures, a second Cu deposition process with a small current density of -20 mA cm-2 was carried out on current densities of -20 mA cm-2 The two images shown on the right bottom corner are the sample photographs.
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