Recent advancements and manipulation strategies of colloidal Cs2BIBIIIX6 lead-free halide double perovskite nanocrystals
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Double-metallic lead-free halide perovskites, Cs2BIBIIIX6, sharing three-dimensional crystal structure, have been under the spotlight as the promising alternatives for the toxic and instable lead-based counterparts. Interest in Cs2BIBIIIX6 motivates intense research into their colloidal nanocrystals (NCs). Recently, Cs2BIBIIIX6 NCs have made great progress in the optical performance via alloying or doping, but there are still great challenges for optoelectronic applications. In this review, the latest advances of Cs2BIBIIIX6 NCs in synthesis approaches, bandgap engineering, photoluminescence (PL) optimization, and applications are summarized. The focus is put upon the composition–property relationships of Cs2BIBIIIX6 NCs, which is approached by discussing the influences of composition variation on the electronic states, carrier dynamics, and optical properties. The challenges and the corresponding improving strategies in the development of high-effective and stable Cs2BIBIIIX6 NCs for device applications are also highlighted. It is believed that this review can deepen the understanding on this burgeoning material system and shed light on their future research directions.
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Recent advancements and manipulation strategies of colloidal Cs2BIBIIIX6 lead-free halide double perovskite nanocrystals
)
Abstract
Double-metallic lead-free halide perovskites, Cs2BIBIIIX6, sharing three-dimensional crystal structure, have been under the spotlight as the promising alternatives for the toxic and instable lead-based counterparts. Interest in Cs2BIBIIIX6 motivates intense research into their colloidal nanocrystals (NCs). Recently, Cs2BIBIIIX6 NCs have made great progress in the optical performance via alloying or doping, but there are still great challenges for optoelectronic applications. In this review, the latest advances of Cs2BIBIIIX6 NCs in synthesis approaches, bandgap engineering, photoluminescence (PL) optimization, and applications are summarized. The focus is put upon the composition–property relationships of Cs2BIBIIIX6 NCs, which is approached by discussing the influences of composition variation on the electronic states, carrier dynamics, and optical properties. The challenges and the corresponding improving strategies in the development of high-effective and stable Cs2BIBIIIX6 NCs for device applications are also highlighted. It is believed that this review can deepen the understanding on this burgeoning material system and shed light on their future research directions.
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Acknowledgements
This work was financially supported by the Natural Science Foundation of Fujian Province (No. 2021J01315), and Quanzhou Scientific Research Project (No. 2021GZ4).
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