Intrinsic anion diffusivity in lead halide perovskites is facilitated by a soft lattice Article Swipe

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Halide Materials science Ion Chemical physics Heterojunction Lattice (music) Thermal diffusivity Perovskite (structure) Nanowire Semiconductor Crystallite Nanotechnology Nanoscopic scale Atomic diffusion Optoelectronics Crystallography Chemistry Inorganic chemistry Physics Thermodynamics Organic chemistry Metallurgy Acoustics

Minliang Lai , Amaël Obliger , Dylan Lu , Christopher S. Kley , Connor G. Bischak , Qiao Kong , Lei Teng , Letian Dou , Naomi S. Ginsberg , David T. Limmer , Peidong Yang ·

YOU? · · 2018 · Open Access · · DOI: https://doi.org/10.1073/pnas.1812718115 · OA: W2899786547

Significance Understanding and controlling the ion migration in a solid-state semiconductor is essential for device performance in modern photonics, electronics, and optoelectronics. Direct microstructural observation and atomic-scale mechanism of the intrinsic lattice diffusion are still highly challenging. Here, we report the direct visualization of halide anion interdiffusion in CsPbCl 3 –CsPbBr 3 single crystalline nanowire heterojunctions via nanoscale imaging, allowing for the direct measuring of intrinsic lattice diffusivities. The intrinsic halide diffusivities were found to be several orders of magnitudes lower than those reported in polycrystalline thin films. Together with multiscale modeling, we further demonstrate how anionic diffusion in lead halides is determined by low barriers to vacancy hopping and facilitated by the soft perovskite lattice.