Issue 29, 2020

Understanding of the aging pattern in quantum dot light-emitting diodes using low-frequency noise

Abstract

The negative and positive aging effects of quantum dot (QD) light-emitting diodes (QLEDs) have received considerable attention in recent years and various analysis methods have been discussed. Here, we introduce a new approach to understand the aging effect of QLEDs, which is to diagnose the behavior of carriers and traps at interfaces between each layer of the QLEDs and inside the layers themselves. In particular, low-frequency noise (LFN) measurement and the analysis of current in the QLEDs were introduced to investigate the trapping/de-trapping behaviors of carriers in the defect states in the devices. A flicker noise was observed before the carriers are injected into the QD emitting layer, while the exciton generation–recombination (G–R) noise and shot noise were observed when the electrons were injected. A correlated noise, which is the correlated model of the trapping/de-trapping of the carriers near and/or inside the QDs and the exciton recombination, was also observed above the turn-on voltage. In addition, when the devices were aged with a constant current source, rapid increases in the luminance and external quantum efficiency (EQE) were observed for up to 50 h. After 100 h of the current aging, however, the devices were negatively aged with the reduced EQE. The LFN analysis results imply that the aging phenomena mainly depend on the trapping/de-trapping of carriers. In addition to the LFN analysis, we also investigated the current density–voltage–luminance and capacitance–voltage characteristics of the devices to clarify the aging behaviors in QLEDs.

Graphical abstract: Understanding of the aging pattern in quantum dot light-emitting diodes using low-frequency noise

Supplementary files

Article information

Article type
Paper
Submitted
06 Mar 2020
Accepted
04 Jun 2020
First published
08 Jun 2020

Nanoscale, 2020,12, 15888-15895

Understanding of the aging pattern in quantum dot light-emitting diodes using low-frequency noise

K. Lee, J. Yun, S. Lee, J. Song, Y. Kim, J. Kwak and G. Kim, Nanoscale, 2020, 12, 15888 DOI: 10.1039/D0NR01885F

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