Band alignment study of the Sr1-xCaxTaO2N / H2O interface for photoelectrochemical devices and Hydrogen production

Abstract

Hydrogen is one of the most promising candidates for clean energy production. Photoelectrochemical devices look promising for the decomposition of the water molecule into 2H2 + O2. Oxynitrides, like the solid solution Sr1-xCaxO2N, are good candidates due to the low band gap that lies into the maximum zone of the solar radiation spectrum. A necessary condition for the photoelectrochemical process to work without a bias voltage is that the minimum of the semiconductor conduction band must be more positive than the reduction potential H+ to H2, whereas the maximum of the semiconductor valence band must be more negative than the oxidation potential of H2O to O2. Thus, band alignment studies in interfaces of semiconductors with water become of great importance. They present several subtleties, as different or simplistic modelling will result in few decimes of eV difference that would lead to a wrong prediction in the alignment. So, to find a trustful method is desirable. In this work, first principles calculations based on density functional theory (DFT) in the all electron and the pseudopotential approaches have been performed for the analysis of the band alignment in Sr1-xCaxO2N /H2O interfaces. A detailed study of the modelling of the surface, supercells, and interface with water molecules was done. Experimental data were taken for the structures and photoelectrochemical behaviour and well reproduced by the methodology implemented. The analysis carried out led to theoretical results compatible with the experimental results: the calculations show that the Sr1-xCaxO2N /H2O is suitable for photoelectrochemical applications, and the partial substitution of Sr by Ca enables the gap and alignment tuning thus enhancing the complex performance.

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