Interfacial engineering at hole transport layer and perovskite interface for efficient perovskite based light emitting diodes
Due to its defect tolerant nature, high photoluminescence quantum yield, and narrow photoluminescence full width half maximum, organic inorganic halide perovskites have garnered significant attention especially for light emitting diodes application, the main focus of this project. Named after...
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| Format: | Final Year Project |
| Language: | English |
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Nanyang Technological University
2022
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| Online Access: | https://hdl.handle.net/10356/157137 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Due to its defect tolerant nature, high photoluminescence quantum yield, and narrow
photoluminescence full width half maximum, organic inorganic halide perovskites
have garnered significant attention especially for light emitting diodes application, the
main focus of this project. Named after its crystal structure, it has an APbX3 structure
where A is the organic or inorganic cation and X is the halide anions. Bulky organic
cation can also be added into the structure to break the 3D [PbX6] octahedra network
to form quasi 2D structures to enhance the carrier confinement in the system. Among
various parameters, hole transport layer (HTL) and perovskite emitter interfaces are
one of the most important parameters that heavily dictate the performance of
perovskite-based light emitting diodes (PeLED). The interface quality influences both
the interfacial defect density and the quality of bulk perovskite grown on top which are
crucial for PeLED performances. Herein, interfacial engineering at HTL/perovskite
interfaces were done by either introducing an electron blocking layer or increasing the
halide ions at the interfaces.
Poly(N,N′ -bis(4-butylphenyl)-N,N′ -bis(phenyl) benzidine) (poly-TPD) was used as
an excellent hole transport material with the favourable energy levels and electron
blocking capability. However due to its very hydrophobic nature, the need for surface
modification was recognized. Various treatments were evaluated, i.e.
Dimethylformamide solvent, Poly(9,9-bis(3’-(N,N-dimethyl)-N-ethylammoinium-propyl-2,7-fluorene)-alt-2,7-(9,9-dioctylfluorene))dibromide (PFNBr), Ultraviolet
(UV) Ozone treatment and Argon plasma treatment. The changes on the optical,
electrical, and interfacial properties upon treatments were characterized in depth.
Amongst these 4 approaches, successful incorporation of Poly-TPD layer was
achieved by UV Ozone treatment. In addition to that, an impressive external quantum
efficiency (EQE) enhancement (~200%) was reflected by UV Ozone treated Poly-TPD
devices as compared to the other devices. While pin holes in the perovskite emitter
were still found in the current system, further optimization to eliminate them would
guarantee an even higher EQE enhancement.
Literatures indicate that halide-rich interfaces were useful to passivate uncoordinated
Pb2+ interface defects which promote higher radiative recombination leading to
efficient PeLED. Halide acids, i.e. Hydrochloric and Hydrobromic acid, were utilised
and the effect of acid concentration on the physical, optical, and electrical properties
of HTL were evaluated. Despite its potential, no significant improvement on the
conductivity and device performance were found. |
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