| Literature DB >> 30079219 |
Wei Cui1, Wenzhe Niu1,2, René Wick-Joliat1, Thomas Moehl1, S David Tilley1.
Abstract
In this work, we demonstrate that buried junction photocathodes featuring an <span class="Disease">ALD <span class="Chemical">TiO2 protective overlayer can be readily characterized using a variation of the dual working electrode (DWE) technique, where the second working electrode (WE2) is spatially isolated from the hydrogen-evolving active area. The measurement of the surface potential during operation enables the operando deconvolution of the photovoltaic and electrocatalytic performance of these photocathodes, by reconstructing J-ΔV curves (reminiscent of photovoltaic J-V curves) from the 3-electrode water splitting data. Our method provides a clearer understanding of the photocathode degradation mechanism during stability tests, including loss of the catalyst from the surface, which is only possible in our isolated WE2 configuration. A pn+Si/TiO2 photocathode was first investigated as a well behaved model system, and then the technique was applied to an emerging material system based on Cu2O/Ga2O3, where we uncovered an intrinsic instability of the Cu2O/Ga2O3 junction (loss of photovoltage) during long term stability measurements.Entities:
Year: 2018 PMID: 30079219 PMCID: PMC6052736 DOI: 10.1039/c8sc01453a
Source DB: PubMed Journal: Chem Sci ISSN: 2041-6520 Impact factor: 9.825
Fig. 1Schematic illustration of (a) the DWE configuration used during PEC measurements with a pn+Si/TiO2/Pt photocathode and (b) the structure of the sensing electrode WE2, located a small distance (∼1 mm) away from the illuminated area, separated by a thin coating of opaque epoxy (not to scale). For simplicity, the band bendings at the interfaces of the highly doped n+-Si and TiO2 have been omitted. (c) The J–V1 and J–ΔV curves of pn+Si/TiO2/Pt(ed), collected by a LSV scan toward negative potential with a scan rate of 10 mV s–1 in 0.5 M H2SO4. ΔV = V1 – V2. (d) V2 and J values of pn+Si/TiO2/Pt(ed) with stepwise controlled V1 under illumination. Each V1 step lasts 30 s. Pt(ed) indicates that the Pt was deposited by electrodeposition.
Fig. 2(a) J–V1 (solid) and J–ΔV curves (dashed) of pn+Si/TiO2/Pt(ed) before and after a 2 h stability test, collected by a LSV scan with a scan rate of 50 mV s–1 towards negative potential in 0.5 M H2SO4. (b) Changes in V2 and J during a 2 h stability test. V1 is held at 0 VRHE. (c) J–ΔV curves (dashed) of pn+Si/TiO2/Pt(ed) and the corresponding J–V1 curves (solid). All data are collected under simulated one sun illumination.
Fig. 3(a) Comparison of J–V1 curves between pn+Si/TiO2/Pt(ed) and pn+Si/TiO2/Pt(sp), collected by a LSV scan with a scan rate of 10 mV s–1 towards negative potential in 0.5 M H2SO4. (b) J–ΔV curves (dashed) of pn+Si/TiO2/Pt(ed) and pn+Si/TiO2/Pt(sp), combined with their J–V1 curves (solid). All data are collected under illumination. For comparison, the performance of pn+Si/TiO2/Pt(sp) with similar photocurrent densities as pn+Si/TiO2/Pt(ed), by increasing the light intensity, is also displayed (green solid and dashed curves).
Fig. 4(a) Schematic structure of a Cu2O/Ga2O3/TiO2/Pt(sp) photocathode. The thickness of Ga2O3 and TiO2 ALD-layers are 20 and 100 nm, respectively. WE1 controls the back contact potential V1 and WE2 measures the surface potential V2. (b) J–ΔV curves (dashed) of Cu2O/Ga2O3/TiO2/Pt(sp) before and after 2 h stability test, overlaid with the corresponding J–V1 curves (solid).