AI Article Synopsis
- ZnSeTe quantum dots (QDs) are effective blue emitters for QLEDs but face efficiency challenges due to exciton loss at the QD and electron transport layer (ETL) interface.
- A hybridization strategy using amino alcohols during ZMO nanoparticle synthesis slows down their growth, reduces defects, and enhances coordination with metal cations, which mitigates emission quenching and boosts carrier injection.
- The optimized blue ZnSeTe QLED achieves a high external quantum efficiency (EQE) of 8.6% with minimal efficiency drop at high current densities, while traditional methods lead to much poorer performance and shorter lifetimes.
Article Abstract
ZnSeTe quantum dots (QDs) have been employed as promising emitters for blue QD-based light-emitting diodes (QLEDs) due to their unique optoelectronic properties and environmental friendliness. However, such QLEDs usually suffer from serious efficiency roll-off primarily stemming from exciton loss at the interface of the QD layer and the ZnMgO (ZMO) electron transport layer (ETL), which remarkably hinders their application in flat-panel displays. Herein, we propose an hybridization strategy that involves the pre-introduction of amino alcohols into the reaction solution. This strategy effectively suppresses the nucleophilic condensation process by facilitating the coordination of ammonium and hydroxyl groups with metal cations (M, Zn and Mg). It slows down the growth rate of ZMO nanoparticles (NPs) while simultaneously facilitating M-O coordination, resulting in the synthesis of small-sized and low-defect ZMO NPs. Notably, this hybridization approach not only alleviates emission quenching at the QDs/ETL interface but also elevates the energy level of the ETL for enhancing carrier injection. We further investigated the impact of amino alcohols with varying carbon-chain lengths on the performance of ZMO NPs and the corresponding LED devices. The optimal blue ZnSeTe QLED demonstrates an impressive EQE of 8.6% with only an ∼11% drop when the current density is increased to 200 mA cm, and the device operating lifetime extends to over 1300 h. Conversely, the device utilizing traditionally post-treated ZMO NPs as the ETL exhibits 45% efficiency roll-off and device lifetime of merely 190 h.
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| http://dx.doi.org/10.1039/d4nr01515k | DOI Listing |
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