Synthesis and characterization of new organic–inorganic hybrid compounds based on Sb, with a perovskite like structure

Perovskite Dimensional Evolution Through Cations Engineering to Tailor the Detection Limit in Hard X-ray Response

Halide perovskites with various compositions are potential candidates in low-dosage X-ray detection due to their large sensitivity and tunable optoelectronic properties. Here, cations engineering induced dimensional evolution of halide perovskites between 0D, 2D, and 3D is reported. Centimeter-sized 2D lead-free perovskite single-crystal of 4-fluorophenethylammonium antimony iodide (FPEA₃ SbI₆ ) is synthesized. In contrast to the 0D phenethylammonium antimony iodide (PEA₃ Sb₂ I₉ ), face-shared [Sb₂ I₉ ]^3- of the bi-octahedral structure of PEA₃ Sb₂ I₉ is split into corner-shared [SbI₆ ]^3- by intermolecular interactions and steric hindrance of FPEA⁺ ions in 2D FPEA₃ SbI₆ . Two Sb³⁺ ions share three octahedral [SbI₆ ]^3- , leaving one-third of Sb³⁺ vacancies in the framework of FPEA₃ SbI₆ . Furthermore, Sn²⁺ ions can be filled into the vacancies to form continuous 2D frameworks to tune the anisotropic conductivity and device sensitivity to hard X-rays. The dimensional evolution of perovskite single-crystals from 3D to 2D or 0D to 2D maximizes the signal/noise ratio to facilize the adjustability of detection limit in hard X-ray detection, which is determined by both device sensitivity and device noise current. A record low detection limit coefficient of 0.65 is achieved in the 2D FPEA₃ SbSn_0.5 I₇ single-crystal sample, which results from selective charges collection over mobile ions/noise current in the 2D perovskite structure.