NKU Team Makes Significant Progress on Photoelectrocatalytic Water Splitting for Hydrogen Production

2023-12-07

Recently, the research team led by Professor Jingshan Luo of the College of Electronic Information and Optical Engineering at Nankai University published the latest research results in the field of the photoelectrocatalytic water splitting for hydrogen production in the internationally renowned journal Nature Communications. The research team introduced dual buffer layers using atomic layer deposition (ALD) to significantly improve the photovoltage of the Cu2O photocathode. 


Professor Jingshan Luo has been focusing on improving the photocatalytic activity of Cu2O for many years. With the team, they achieved a saturation photocurrent density of the Cu2O photocathode of 10 mA cm-2 using nanowire structure for the first time internationally (Nano Letters, 16, 1848-1857, 2016). Subsequently, using a Ga2O3 buffer layer, they successfully increased the onset potential of the Cu2O photocathode to the recorded value of 1 V (vs. RHE) (Nature Catalyst, 1, 412-420, 2018). Improving the photovoltage of the Cu2O photocathode helps to improve the solar-to-hydrogen (STH) conversion efficiency of un-biased tandem devices. The current onset potential of the Cu2O photocathode can reach 1 V (vs. RHE), which is still lower than the theoretical value of 1.6 V. Thus, there is significant room for improvement.


Previous studies mostly focused on optimizing the band alignment between Cu2O and the n-type buffer layer to improve the photovoltage of Cu2O photocathodes. However, the band alignment between the n-type buffer layer and the protective layer is often ignored. According to literature analysis and electrochemical impedance spectroscopy (EIS) measurements results, doctoral students Jinshui Cheng and Linxiao Wu, guided by Professor Jingshan Luo, found that a potential barrier existed at the interface of the n-type buffer layer (Ga2O3) and the protective layer (TiO2), which decreased the photovoltage and fill factor of the Cu2O photocathode. Next, they inserted a second buffer layer (ZnGeOx) using atomic layer deposition (ALD) between Ga2O3 and TiO2 to form an energy-level gradient, which eliminated the potential barrier and improved the band alignment. As a result, the photovoltage of the Cu2O photocathode was successfully increased to 1.07 V (vs. RHE).


The authors revealed the transport behavior of photo-generated charge carriers at different interfaces by comparing the resistance changes of photocathodes with a single buffer layer (Ga2O3) and dual buffer layers (Ga2O3/ZnGeOx) under different bias. The operando EIS measurements showed that, when compared to the single buffer layer device, the dual buffer layers device could let the Cu2O photocathode eliminate the unfavorable potential barrier and charge transfer resistance at the Ga2O3/TiO2 interface. In addition, the author revealed that an energy-level gradient was formed between Ga2O3 and TiO2 after the introduction of the ZnGeOx buffer layer, thereby optimizing the band alignment between the buffer layer and the protective layer, reducing the energy loss, and ultimately improving the photovoltage of the Cu2O photocathode.



Figure a, Schematic diagram of the energy-level structure and charge transfer behaviour of the Cu2O photocathode with dual buffer layers. b, Current density-voltage curves of different Cu2O photocathodes under illumination (AM 1.5G, 100 mW cm-2). c, Statistical onset potential for different Cu2O photocathodes. d, Resistance values and their change trends of the Cu2O photocathode with dual buffer layers under different bias voltages


In summary, this work emphasizes the importance of the band alignment between the n-type buffer layer and the protective layer and proposes dual buffer layers strategy to improve the photovoltage of the Cu2O photocathode, providing a new idea for improving the performance of other heterojunction devices.


Nankai University is the sole completion unit and communication unit for this work. Professor Jingshan Luo from the College of Electronic Information and Optical Engineering at Nankai University is the corresponding author of this paper, and Jinshui Cheng, a 2020 doctoral student from the College of Electronic Information and Optical Engineering at Nankai University, is the first author.


Article Link: https://www.nature.com/articles/s41467-023-42799-x