In/Bi-based Direct- and Indirect-Gap Hybrid Double-Perovskite-Derived 1D Halides with Near-Unity Quantum Yield via Sb<sup>3+</sup> Doping
Ruiqian Li, Yifan Zhou, Xuanyu Zhang, Jiawei Lin, Jian Chen, Congcong Chen, Xin Pan, Pan Wang, Rui Chen, Jun Yin, Lingling Mao
Abstract
The hybrid halide double-perovskite family is a highly diverse system that allows a wide range of property tunings via structural variations. Using organic components instead of small A -site cations to reduce the dimensionality of the structure and doping metal cations can modulate their structure and improve the optoelectronic performance. Here, by introducing an organic cationic ligand morpholine (Mor), we report on a new family of double-perovskite-derived halides (Mor) 2 A BX 6 ( A = Na, K; B = In, Bi; X = Cl, Br) with several unique types of one-dimensional (1D) structures constituted by [ AX 4 O 2 ] and [ BX 6 ] octahedron units. These materials are nonemissive at room temperature, while with an Sb 3+ -doping strategy, the photoluminescence can be drastically enhanced. For (Mor) 2 KIn X 6, their quantum efficiencies are improved to near unity via Sb 3+ doping. Meanwhile, for (Mor) 2 KBi X 6, the photoluminescence improvement from Sb 3+ doping is negligible. With density functional theory calculations, (Mor) 2 KInBr 6 and (Mor) 2 KBiBr 6 have been identified to have direct- and indirect- band gap, respectively. This work expands a new material space for organic–inorganic hybrid double-perovskite-derived materials and provides insights into tuning their optical properties.