Unveiling the Interaction Mechanisms of Electron and X-ray Radiation with Halide Perovskite Semiconductors using Scanning Nanoprobe Diffraction

The interaction of high-energy electrons and X-ray photons with beam-sensitive semiconductors such as halide perovskites is essential for the characterization and understanding of these optoelectronic materials. Using nanoprobe diffraction techniques, which can investigate physical properties on the nanoscale, studies of the interaction of electron and X-ray radiation with state-of-the-art (FA(0.79)MA(0.16)Cs(0.05))Pb(I0.83Br0.17)(3) hybrid halide perovskite films (FA, formamidinium; MA, methylammonium) are performed, tracking the changes in the local crystal structure as a function of fluence using scanning electron diffraction and synchrotron nano X-ray diffraction techniques. Perovskite grains are identified, from which additional reflections, corresponding to PbBr2, appear as a crystalline degradation phase after fluences of 200 e(-) angstrom(-)(2). These changes are concomitant with the formation of small PbI2 crystallites at the adjacent high-angle grain boundaries, with the formation of pinholes, and with a phase transition from tetragonal to cubic. A similar degradation pathway is caused by photon irradiation in nano-X-ray diffraction, suggesting common underlying mechanisms. This approach explores the radiation limits of these materials and provides a description of the degradation pathways on the nanoscale. Addressing high-angle grain boundaries will be critical for the further improvement of halide polycrystalline film stability, especially for applications vulnerable to high-energy radiation such as space photovoltaics.

Automated summary

The interaction of high-energy electrons and X-ray photons with beam-sensitive semiconductors is investigated using nanoprobe diffraction techniques. The changes in the local crystal structure of hybrid halide perovskite films are tracked as a function of fluence, revealing the formation of PbBr2 and PbI2 crystallites, as well as the presence of pinholes. This study emphasizes the importance of addressing high-angle grain boundaries for improving the stability of halide polycrystalline films, especially for applications vulnerable to high-energy radiation.