文摘
Through density functional theory calculations, we show that the alloy perovskite system BaZrb>1–xb>Tib>xb>Sb>3b> (x < 0.25) is a promising candidate for producing high power conversion efficiency (PCE) solar cells with ultrathin absorber layers. To maximize the minority carrier lifetime, which is important for achieving high PCE, the defect calculations show that BaZrb>1–xb>Tib>xb>Sb>3b> films should be synthesized under moderate (i.e., near stoichiometric) growth conditions to minimize the formation of deep-level defects. The perovskite BaZrSb>3b> is also found to exhibit ambipolar self-doping properties, indicating the ability to form homo p–n junctions. However, our theoretical calculations and experimental solid-state reaction efforts indicate that the doped perovskite BaZrb>1–xb>Tib>xb>Sb>3b> (x > 0) may not be stable under thermal equilibrium growth conditions. Calculations of decomposition energies suggest that introducing compressive strain may be a plausible approach to stabilize BaZrb>1–xb>Tib>xb>Sb>3b> thin films.