A hybrid-ligand exchange strategy for high-performance PbSe quantum dot short-wave infrared photodetectors†

IF 5.1 2区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of Materials Chemistry C Pub Date : 2025-06-19 DOI:10.1039/D5TC02115D

Ya Wang, Min Chen, Manning Hu, Anxin Jiao, Faxin Wang, Xiaolong Zheng, Wanqing Li, Xin Tang and Huicheng Hu

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引用次数: 0

Abstract

Lead selenide (PbSe) colloidal quantum dots (CQDs) are promising candidates for short-wave infrared (SWIR) photodetectors due to their low-cost fabrication and solution processability. However, conventional ligand exchange strategies, such as treatment with 1,2-ethanedithiol (EDT), usually lead to incomplete defect passivation and undesirable doping characteristics. Here, we developed a hybrid-ligand strategy by combining EDT and zinc iodide (ZnI₂) to simultaneously passivate surface defects and modulate the doping type of PbSe CQD films. As a result, the photodetector responsivity improves from 0.04 A W⁻¹ to 0.40 A W⁻¹, and the specific detectivity increases from 3.4 × 10¹⁰ Jones to 2.8 × 10¹¹ Jones at 500 Hz under zero bias. The optimized device exhibits a wide linear dynamic range exceeding 114 dB and a fast response time of 7.3 μs. Finally, the infrared imaging applications of PbSe CQD photodetectors were successfully demonstrated. This work highlights the importance of synergistic surface passivation and doping modulation in enhancing the performance of CQD photodetectors.

Abstract Image

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高性能PbSe量子点短波红外探测器的混合配体交换策略[j]

硒化铅（PbSe）胶体量子点（CQDs）因其制备成本低和溶液可加工性而成为短波红外（SWIR）光电探测器的理想候选材料。然而，传统的配体交换策略，如1,2-乙二醇（EDT）处理，通常会导致不完全的缺陷钝化和不良的掺杂特性。在这里，我们开发了一种混合配体策略，通过结合EDT和碘化锌（ZnI2）来同时钝化表面缺陷并调节PbSe CQD薄膜的掺杂类型。结果表明，光电探测器的响应率从0.04 a W−1提高到0.40 a W−1，比探测率从3.4 × 1010琼斯提高到2.8 × 1011琼斯。优化后的器件具有超过114 dB的宽线性动态范围和7.3 μs的快速响应时间。最后，成功演示了PbSe CQD光电探测器在红外成像中的应用。这项工作强调了协同表面钝化和掺杂调制在提高CQD光电探测器性能方面的重要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Materials Chemistry C MATERIALS SCIENCE, MULTIDISCIPLINARY-PHYSICS, APPLIED

CiteScore

10.80

自引率

6.20%

发文量

1468

期刊介绍： The Journal of Materials Chemistry is divided into three distinct sections, A, B, and C, each catering to specific applications of the materials under study: Journal of Materials Chemistry A focuses primarily on materials intended for applications in energy and sustainability. Journal of Materials Chemistry B specializes in materials designed for applications in biology and medicine. Journal of Materials Chemistry C is dedicated to materials suitable for applications in optical, magnetic, and electronic devices. Example topic areas within the scope of Journal of Materials Chemistry C are listed below. This list is neither exhaustive nor exclusive. Bioelectronics Conductors Detectors Dielectrics Displays Ferroelectrics Lasers LEDs Lighting Liquid crystals Memory Metamaterials Multiferroics Photonics Photovoltaics Semiconductors Sensors Single molecule conductors Spintronics Superconductors Thermoelectrics Topological insulators Transistors