From Distortion to Disconnection: Linear Alkyl Diammonium Cations Tune Structure and Photoluminescence of Lead Bromide Perovskites

Organic ammonium cations play a vital role in building structures and tuning energy bands of organic–inorganic halide perovskites and the consequent photoelectric characteristics. Here, two 2D lead bromide perovskites: flat‐layered (BDA)PbBr4 (BDA = 1, 4‐butanediammonium), corrugation‐layered (PDA)7...

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Bibliographic Details
Published in:Advanced optical materials 2020-04, Vol.8 (8), p.n/a
Main Authors: Han, Ying, Li, Yawen, Wang, Yue, Cao, Guangyue, Yue, Sijia, Zhang, Lijun, Cui, Bin‐Bin, Chen, Qi
Format: Article
Language:English
Subjects:
Banded structure
Broadband
Cations
Density functional theory
diammonium cations
emission mechanism
Energy bands
Energy levels
Excitons
lead bromide perovskites
Materials science
Optics
Perovskites
Photoelectricity
Photoluminescence
Quantum confinement
spatial effect
Tuning
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Summary:Organic ammonium cations play a vital role in building structures and tuning energy bands of organic–inorganic halide perovskites and the consequent photoelectric characteristics. Here, two 2D lead bromide perovskites: flat‐layered (BDA)PbBr4 (BDA = 1, 4‐butanediammonium), corrugation‐layered (PDA)7Pb6Br26 (PDA = 1, 3‐propanediammonium) and a 1D nanobelt‐shaped (EDA)2PbBr6 (EDA = ethylenediammonium) are built to explore their tunable structure, energy bands, and photoluminescence by a series of linear alkyl diammonium cations. Significant “spatial effect” of diammonium cations directly controls the space configurations of these lead bromide perovskites. From 2D (100)‐flat to 1D (110)‐nanobelt, distortions and disconnections of lead bromide layers are beneficial to the quantum confinement and generation of self‐trapping exciton (STE) energy levels of low‐dimensional perovskites. Upon ultraviolet excitation, (BDA)PbBr4, (PDA)7Pb6Br26, and (EDA)2PbBr6 exhibit blue, broadband yellowish white, and “warm” white emissions, respectively. Density functional theory combining STE theory demonstrates their bandgap changes and emission mechanisms. This work provides a basis for tuning the structure of low‐dimensional organic–inorganic halide perovskites for better photochromic properties. Flat‐layered, corrugation‐layered, and nanobelt‐shaped low‐dimensional lead bromide perovskites are built to explore their tunability in structure, energy bands, and photoluminescence by a series of linear alkyl diammonium cations, providing a basis for tuning the structure of low‐dimensional organic–inorganic halide perovskites for better photochromic properties.
ISSN:2195-1071
2195-1071
DOI:10.1002/adom.201902051