Title: Realizing Tunable White Light Emission in Lead-Free Indium(III) Bromine Hybrid Single Crystals through Antimony(III) Cation Doping

Authors: Zhongyuan Li, Gaomin Song, Ye Li*, Le Wang*, Tianliang Zhou, Zheshuai Lin, and Rong-Jun Xie*

Abstract: Low-dimensional metal halide hybrids (OIMHs) have recently been explored as single-component white-light emitters for use in solid-state lighting. However, it still remains challenging to realize tunable white-light emission in lead-free zero-dimensional (0D) hybrid system. Here, a combination strategy has been proposed through doping Sb³⁺ enabling and balancing multiple emission centers toward the multiband warm white light. We first synthesized a new lead-free 0D (C₈NH₁₂)₆InBr₉·H₂O single crystal, in which isolated [InBr₆]^3– octahedral units are separated by large organic cations [C₈NH₁₂]⁺. (C₈NH₁₂)₆InBr₉·H₂O exhibits dual-band emissions with one intense cyan emission and a weak red emission tail. The low-energy ultrabroadband red emission tail can be greatly enhanced by the Sb³⁺ doping. Experimental data and first-principles calculations reveal that the original dominant cyan emission is originated from the organic cations [C₈NH₁₂]⁺ and that the broadband red emission is ascribed to self-trapped excitons in [In(Sb)Br₆]^3–. When the Sb concentration is 0.1%, a single-component warm white-light emission with a photoluminescence quantum efficiency of 23.36%, correlated color temperature of 3347 K, and a color rendering index up to 84 can be achieved. This work represents a significant step toward the realization of single-component white-light emissions in environmental-friendly, high-performance 0D metal halide light-emitting materials.

Full-Link: https://pubs.acs.org/doi/10.1021/acs.jpclett.0c03079