Halide perovskite-chalcohalide nanocrystal heterostructures as a platform for the synthesis and investigation of the CsPbCl₃-CsPbI₃ epitaxial interface

Abstract:Halide exchange in lead-based halide perovskites has been studied extensively. While mixed Cl/Br or Br/I alloy compositions can be formed with no miscibility gaps, this is precluded for mixed Cl/I compositions, due to the large difference in Cl- and I- ionic radii. Here, perovskite-chalcohalide CsPbCl3-Pb4S3Cl2 nanocrystal heterostructures are exploited to study the Cl -> I exchange and to isolate new types of intermediate structures. The epitaxial interface between the Pb4S3Cl2 chalcohalide and the CsPbCl3 perovskite significantly influences the intermediate stages of halide exchange in the perovskite domain, leading to coexisting CsPbCl3 and CsPbI3 domains, thereby delivering segmented CsPbI3-CsPbCl3-Pb4S3Cl2, energetically favorable heterostructures, with partial I-alloying of the CsPbCl3 domain and at the perovskite-chalcohalide interface. The I:CsPbCl3 domain between CsPbI3 and Pb4S3Cl2 enables a gradual lattice expansion across the heterostructure. This design accommodates interfacial strain, with a 5.6% mismatch at the CsPbCl3-CsPbI3 interface and a 3.4% mismatch at the perovskite-chalcohalide interface. Full halide exchange leads to CsPbI3-Pb4S3Cl2 heterostructures. Both in intermediate and fully exchanged heterostructures, the CsPbI3 domain is emissive. In the intermediate structures, the band alignment between the two perovskite domains is type-I, with the carriers photogenerated in the CsPbCl3 domain quickly transferring to the CsPbI3 domain, where they can recombine radiatively.

Publication year:2025

Keywords:Physics, Materials science, Multidisciplinary chemistry, Physical chemistry, Applied physics, Physics of solids, fluids and plasmas

Accessibility:Open