Scalable Photoelectrochemical Cell for Overall Solar Water Splitting into H2 and H2O2

Aqueous photoelectrochemical (PEC) cells have been considered a scalable technology to convert solar energy to H2 but still suffer from sluggish water oxidation kinetics and downstream gas separation. Here we demonstrate a PEC water splitting into H2O2 and H2 by employing a CaSnO3/SrTiO3/BiVO4 (CSO/STO/BVO) photoanode to simultaneously address the above two problems. The CSO as cocatalyst selectively oxidizes water to H2O2 with a Faradaic efficiency of 90%, while the STO interlayer promotes the charge separation by an inner polarization field. The scalability potential is demonstrated by 144 cm2 array panel reactors, which achieve an industrial-scale peak photocurrent of 0.11 A under a natural irradiance of 862 W·m–2. The proposed incidence-inclination angle analysis finds the optimum operation for array panel reactors to achieve the highest land-to-photocurrent efficiency. This renovated view of the PEC cell design may enable further optimization of industrial applications.