npj Computational Materials (Jul 2021)

Modelling charge transport and electro-optical characteristics of quantum dot light-emitting diodes

  • Sung-Min Jung,
  • Tae Hoon Lee,
  • Sang Yun Bang,
  • Soo Deok Han,
  • Dong-Wook Shin,
  • Sanghyo Lee,
  • Hyung Woo Choi,
  • Yo-Han Suh,
  • Xiang-Bing Fan,
  • Jeong-Wan Jo,
  • Shijie Zhan,
  • Jiajie Yang,
  • Chatura Samarakoon,
  • Yoonwoo Kim,
  • Luigi G. Occhipinti,
  • Gehan Amaratunga,
  • Jong Min Kim

DOI
https://doi.org/10.1038/s41524-021-00591-9
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 11

Abstract

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Abstracts Quantum dot light-emitting diodes (QD-LEDs) are considered as competitive candidate for next-generation displays or lightings. Recent advances in the synthesis of core/shell quantum dots (QDs) and tailoring procedures for achieving their high quantum yield have facilitated the emergence of high-performance QD-LEDs. Meanwhile, the charge-carrier dynamics in QD-LED devices, which constitutes the remaining core research area for further improvement of QD-LEDs, is, however, poorly understood yet. Here, we propose a charge transport model in which the charge-carrier dynamics in QD-LEDs are comprehensively described by computer simulations. The charge-carrier injection is modelled by the carrier-capturing process, while the effect of electric fields at their interfaces is considered. The simulated electro-optical characteristics of QD-LEDs, such as the luminance, current density and external quantum efficiency (EQE) curves with varying voltages, show excellent agreement with experiments. Therefore, our computational method proposed here provides a useful means for designing and optimising high-performance QD-LED devices.