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Colloidal Mn 2+ Doped 2D ( n =1) Lead Bromide Perovskites: Efficient Energy Transfer and Role of Anion in Doping Mechanism
Author(s) -
Usman Muhammed Haris Palattuparambil,
Bakthavatsalam Rangarajan,
Kundu Janardan
Publication year - 2018
Publication title -
chemistryselect
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.437
H-Index - 34
ISSN - 2365-6549
DOI - 10.1002/slct.201801248
Subject(s) - dopant , doping , quantum yield , materials science , chemical physics , phosphor , exciton , chemistry , nanotechnology , optoelectronics , condensed matter physics , optics , physics , fluorescence
Mn 2+ doping directly into APbCl 3 type 3D nanocrystals, manifesting host to dopant energy transfer, have been heavily reported for illumination and display applications. However, these doped 3D ABX 3 systems have low/modest exciton binding energy. Strongly bound excitons in the doped system can enhance the dopant‐host carrier exchange interactions leading to efficient energy transfer. Reported here is a simple and facile synthesis of colloidal Mn 2+ doped (Butylammonium/octylammonium) 2 PbBr 4 2D ( n =1) perovskites that demonstrate enhanced energy transfer from strongly bound excitons of the host material to the Mn 2+ dopant ions resulting in intense orange‐yellow emission due to spin forbidden internal transition ( 4 T 1 → 6 A 1 ) with the highest quantum yield (Mn 2+ ) of 36%. Consistent with experimental evidences presented here, mechanism of this thermally aided doping process in these 2D systems, very likely, involves halide vacancy and its diffusion that precedes the cation exchange (doping) process. Owing to the high quantum yield, stability in ambient atmosphere, simplicity and scalability of the synthetic procedure, Mn 2+ doped 2D perovskites could be beneficial as color converting phosphor material and can be utilized to further explore their magneto‐optoelectronic properties.