An n-Si/n-Fe2O3 Heterojunction Tandem Photoanode for Solar Water Splitting

Few metal oxide photoanodes are able to reduce protons to hydrogen because their conduction band minimum is located at too positive potentials. This can be remedied by biasing the photoanode with a photovoltaic cell placed behind the photoanode. The disadvantage of such a tandem device is the rather complicated structure. Here, we demonstrate a very simple monolithic heterojunction tandem photoanode based on n-Si and n-type alpha-Fe2O3. Detailed characterization of this system in a basic planar configuration reveals that the silicon generates a photovoltage of similar to 0.3 V, and that the heterojunction functions as a D4 tandem device in which the absorption of two photons leads to one high-energy electron in the external circuit. No Fermi level pinning occurs at the Si/Fe2O3 interface, and the tandem photoanode is thermodynamically able to split water without the need for an external bias potential. This suggests that the n-Si/n-Fe2O3 heterojunction photoanode is a promising system for solar water splitting.