%0 Journal Article
%J Chemistry of Materials
%D 2017
%T Efficient exciton to dopant energy transfer in Mn2+-Doped (C4H9NH3)2PbBr4 two-dimensional (2D) layered perovskites
%A Biswas, A.
%E Bakthavatsalam, R.
%Y Kundu, J.
%K Doping (additives)
%K Energy Efficiency
%K Energy Transfer
%K Exchange interactions
%K Excitons
%K Light Emitting Diodes
%X Three-dimensional ABX3 perovskite material has attracted immense interest and applications in optoelectronic devices, because of their enabling properties. Recently, Mn2+ doping directly into APbCl3-type three-dimensional (3D) nanocrystals, manifesting host-to-dopant energy transfer, have been reported for LED display applications. Strongly bound excitons in the doped system can enhance the dopant-carrier exchange interactions, leading to efficient energy transfer. Here, we report the simple and scalable synthesis of Mn2+-doped (C4H9NH3)2PbBr4 two-dimensional (2D) layered perovskites. The Mn2+-doped 2D perovskite shows enhanced energy transfer efficiency from the strongly bound excitons of the host material to the d electrons of Mn2+ ions, resulting in intense orange-yellow emission, which is due to spin-forbidden internal transition (4T1 → 6A1) with the highest quantum yield (Mn2+) of 37%. Because of this high quantum yield, stability in ambient atmosphere, and simplicity and scalability of the synthetic procedure, Mn2+-doped 2D perovskites could be beneficial as color-converting phosphor material and as energy down-shift coating for perovskite solar cells. The newly developed Mn2+-doped 2D perovskites can be a suitable material to tune dopant-exciton exchange interactions to further explore their magneto-optoelectronic properties.
%B Chemistry of Materials
%V 29
%P 7816-7825
%8 SEP
%G eng
%N 18
%9 Journal Article
%3 Foreign
%4 9.407
%R 10.1021/acs.chemmater.7b02429