Group-VA Doped ZnO Injection Layer for Bright and Efficient Perovskite Light-Emitting Diodes

Xiaoyu Yang; Yongqiang Ji; Qiuyang Li; Qixuan Zhong; Hong Li; Zhangyuchang Lu; Hao Hsin Chen; Yanju Wang; An Hu; Shunde Li; Li Ma; Le Li; Yuzhuo Zhang; Yu Chen; Lichen Zhao; Jiang Wu; Xinqiang Wang; Changjun Lu; Rui Zhu

doi:10.1002/adfm.202413517

Group-VA Doped ZnO Injection Layer for Bright and Efficient Perovskite Light-Emitting Diodes

Xiaoyu Yang, Yongqiang Ji^*, Qiuyang Li, Qixuan Zhong, Hong Li, Zhangyuchang Lu, Hao Hsin Chen, Yanju Wang, An Hu, Shunde Li, Li Ma, Le Li, Yuzhuo Zhang, Yu Chen, Lichen Zhao, Jiang Wu^*, Xinqiang Wang, Changjun Lu^*, Rui Zhu

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

Heteroatom doping of the ZnO electron injection layer (EIL) is widely applied to the fabrication of high-performance quantum-dot and perovskite light-emitting diodes (PeLEDs), while group-VA atomic dopant is rarely studied. Here, VA bismuth (Bi) with strong metallicity is screened as a substitution dopant to regulate the colloid size, surface terminal, and defect density of the ZnO precursor. The as-fabricated Bi-doped ZnO (ZnBiO) EIL shows enhanced conductivity, passivated trap states, more n-type nature, and appropriate band alignment with FAPbI₃ (FA: formamidinium), contributing to smooth injection paths with minimal transport losses. Promoted by inhibited hydroxyl terminations of ZnBiO, the FAPbI₃ crystals grown into flat nanocylinder domains with higher crystallinity and area-thickness ratio, leading to a champion PeLED efficiency of 22.3%, a high near-infrared radiance of 684 W sr⁻¹ m⁻², and nearly an order of magnitude extended operational stability, which shows great promise of ZnBiO as the optimal EIL for various LED application scenarios beyond classical ZnMgO.

Original language	English
Article number	2413517
Journal	Advanced Functional Materials
Volume	35
Issue number	3
DOIs	https://doi.org/10.1002/adfm.202413517
Publication status	Published - 15 Jan 2025
Externally published	Yes

Keywords

Bi-doped ZnO
electron injection layer
near-infrared emission
perovskite LED

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10.1002/adfm.202413517

Cite this

Yang, X., Ji, Y., Li, Q., Zhong, Q., Li, H., Lu, Z., Chen, H. H., Wang, Y., Hu, A., Li, S., Ma, L., Li, L., Zhang, Y., Chen, Y., Zhao, L., Wu, J., Wang, X., Lu, C., & Zhu, R. (2025). Group-VA Doped ZnO Injection Layer for Bright and Efficient Perovskite Light-Emitting Diodes. Advanced Functional Materials, 35(3), Article 2413517. https://doi.org/10.1002/adfm.202413517

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title = "Group-VA Doped ZnO Injection Layer for Bright and Efficient Perovskite Light-Emitting Diodes",

abstract = "Heteroatom doping of the ZnO electron injection layer (EIL) is widely applied to the fabrication of high-performance quantum-dot and perovskite light-emitting diodes (PeLEDs), while group-VA atomic dopant is rarely studied. Here, VA bismuth (Bi) with strong metallicity is screened as a substitution dopant to regulate the colloid size, surface terminal, and defect density of the ZnO precursor. The as-fabricated Bi-doped ZnO (ZnBiO) EIL shows enhanced conductivity, passivated trap states, more n-type nature, and appropriate band alignment with FAPbI3 (FA: formamidinium), contributing to smooth injection paths with minimal transport losses. Promoted by inhibited hydroxyl terminations of ZnBiO, the FAPbI3 crystals grown into flat nanocylinder domains with higher crystallinity and area-thickness ratio, leading to a champion PeLED efficiency of 22.3%, a high near-infrared radiance of 684 W sr−1 m−2, and nearly an order of magnitude extended operational stability, which shows great promise of ZnBiO as the optimal EIL for various LED application scenarios beyond classical ZnMgO.",

keywords = "Bi-doped ZnO, electron injection layer, near-infrared emission, perovskite LED",

author = "Xiaoyu Yang and Yongqiang Ji and Qiuyang Li and Qixuan Zhong and Hong Li and Zhangyuchang Lu and Chen, {Hao Hsin} and Yanju Wang and An Hu and Shunde Li and Li Ma and Le Li and Yuzhuo Zhang and Yu Chen and Lichen Zhao and Jiang Wu and Xinqiang Wang and Changjun Lu and Rui Zhu",

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doi = "10.1002/adfm.202413517",

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T1 - Group-VA Doped ZnO Injection Layer for Bright and Efficient Perovskite Light-Emitting Diodes

AU - Yang, Xiaoyu

AU - Ji, Yongqiang

AU - Li, Qiuyang

AU - Zhong, Qixuan

AU - Li, Hong

AU - Lu, Zhangyuchang

AU - Chen, Hao Hsin

AU - Wang, Yanju

AU - Hu, An

AU - Li, Shunde

AU - Ma, Li

AU - Li, Le

AU - Zhang, Yuzhuo

AU - Chen, Yu

AU - Zhao, Lichen

AU - Wu, Jiang

AU - Wang, Xinqiang

AU - Lu, Changjun

AU - Zhu, Rui

PY - 2025/1/15

Y1 - 2025/1/15

N2 - Heteroatom doping of the ZnO electron injection layer (EIL) is widely applied to the fabrication of high-performance quantum-dot and perovskite light-emitting diodes (PeLEDs), while group-VA atomic dopant is rarely studied. Here, VA bismuth (Bi) with strong metallicity is screened as a substitution dopant to regulate the colloid size, surface terminal, and defect density of the ZnO precursor. The as-fabricated Bi-doped ZnO (ZnBiO) EIL shows enhanced conductivity, passivated trap states, more n-type nature, and appropriate band alignment with FAPbI3 (FA: formamidinium), contributing to smooth injection paths with minimal transport losses. Promoted by inhibited hydroxyl terminations of ZnBiO, the FAPbI3 crystals grown into flat nanocylinder domains with higher crystallinity and area-thickness ratio, leading to a champion PeLED efficiency of 22.3%, a high near-infrared radiance of 684 W sr−1 m−2, and nearly an order of magnitude extended operational stability, which shows great promise of ZnBiO as the optimal EIL for various LED application scenarios beyond classical ZnMgO.

AB - Heteroatom doping of the ZnO electron injection layer (EIL) is widely applied to the fabrication of high-performance quantum-dot and perovskite light-emitting diodes (PeLEDs), while group-VA atomic dopant is rarely studied. Here, VA bismuth (Bi) with strong metallicity is screened as a substitution dopant to regulate the colloid size, surface terminal, and defect density of the ZnO precursor. The as-fabricated Bi-doped ZnO (ZnBiO) EIL shows enhanced conductivity, passivated trap states, more n-type nature, and appropriate band alignment with FAPbI3 (FA: formamidinium), contributing to smooth injection paths with minimal transport losses. Promoted by inhibited hydroxyl terminations of ZnBiO, the FAPbI3 crystals grown into flat nanocylinder domains with higher crystallinity and area-thickness ratio, leading to a champion PeLED efficiency of 22.3%, a high near-infrared radiance of 684 W sr−1 m−2, and nearly an order of magnitude extended operational stability, which shows great promise of ZnBiO as the optimal EIL for various LED application scenarios beyond classical ZnMgO.

KW - Bi-doped ZnO

KW - electron injection layer

KW - near-infrared emission

KW - perovskite LED

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JF - Advanced Functional Materials

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M1 - 2413517

ER -

Group-VA Doped ZnO Injection Layer for Bright and Efficient Perovskite Light-Emitting Diodes

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