posted on 2021-12-29, 20:14authored byLaura E. Mundt, Fei Zhang, Axel F. Palmstrom, Junwei Xu, Robert Tirawat, Leah L. Kelly, Kevin H. Stone, Kai Zhu, Joseph J. Berry, Michael F. Toney, Laura T. Schelhas
The
structural stability of the metal halide perovskite (MHP) absorber
material is crucial for the long-term solar cell stability in this
thin-film photovoltaic technology. Here, we use mixed A-site FA0.83Cs0.17PbI3 to demonstrate that nanoscale
compositional heterogeneity can serve as initiation sites for more
macroscale, irreversible phase segregation, which causes device performance
degradation. Probing compositional heterogeneity on length scales
that has not been detected with conventional characterization techniques,
we analyze the tetragonal to cubic phase transition behavior to indirectly
determine the level of nanoscale compositional heterogeneity in the
initial films. Further, we show that the thermal annealing conditions
of the MHP layer during film processing influence the initial nanoscale
compositional heterogeneity, and changing these processing conditions
can be used to improve the device performance stability. The insights
into structural degradation mechanisms initiated by nanoscale compositional
heterogeneity and the proposed mitigation strategies will help guide
the way toward long-term stable MHP solar cells.