Photogating Enhanced Photodetectors Dominated by Rubrene Nanodots Modified SnS2 Films

IF 4.5 3区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY 2D Materials Pub Date : 2024-01-03 DOI:10.1088/2053-1583/ad1a6d
Guoxiang Si, Fangjun Liu, Lizhao Su, Zhaoxuan Wu, Qi Zhang, Shuoqi Sun, Hongbin Zhang
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Abstract

The hybrid-induced photogating effect is considered as an effective way for photoconductance modulating in low-dimensional photodetectors. Besides, through constructing the local photogate vertical heterostructures on 2D SnS2 surface can significantly increase its photoconductive gain. However, the potential of this photogain mechanism for SnS2 films has not yet been revealed in practical photodetection devices. To investigate its special advantages on promoting the optical-sensing activity, the high-quality SnS2 films with discrete, micro-area, and uniform rubrene-nanodots modification have been prepared. Benefit from the local interfacial photogating effect induced by hole trap states by rubrene-nanodots, the light-absorption and carrier-excitation efficiencies were significantly enhanced. Afterwards, the high-performance photodetector was designed based on the photogate vertical heterostructures of rubrene-nanodots/SnS2, which demonstrated an enhanced photoelectric response to 1064 nm light. Note that the maximum photocurrent density, photoresponsivity, and photodetectivity can reach up to 0.389 mA·cm-2, 388.71 mA·W-1, and 1.13×1010 Jones, respectively. Importantly, the optimal band-structure offsets accelerated the localized hole transfer from SnS2 film to rubrene-nanodots. The trapped holes in rubrene-nanodots induced an enhanced interface gating effect, which may help to modulate the number and lifetime of excess electrons under light illuminations. These superior features make the newly-developed photodetector be suitable for future multifunctional photodetection applications.
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由铷原子纳米点修饰的 SnS2 薄膜主导的光ogating 增强型光电探测器
杂化诱导的光ogating效应被认为是低维光电探测器光电导调制的有效方法。此外,通过在二维 SnS2 表面构建局部光电门垂直异质结构,可以显著提高其光电导增益。然而,SnS2 薄膜的这种光增益机制在实际光电检测器件中的潜力尚未显现。为了研究其在促进光传感活性方面的特殊优势,我们制备了具有离散、微面积和均匀的 Rubrene-nanodots 修饰的高质量 SnS2 薄膜。得益于鲁宾烷-纳米点空穴陷阱态诱导的局部界面光ogating效应,光吸收效率和载流子激发效率显著提高。随后,基于红宝石-纳米点/SnS2 的光栅垂直异质结构设计了高性能光电探测器,该探测器对 1064 纳米光的光电响应增强。值得注意的是,最大光电流密度、光致发光率和光电探测率分别高达 0.389 mA-cm-2、388.71 mA-W-1 和 1.13×1010 Jones。重要的是,最佳带状结构偏移加速了从 SnS2 薄膜到红宝石-纳米点的局部空穴传输。被困在红宝石-纳米点中的空穴诱导了增强的界面门控效应,这可能有助于在光照下调节过剩电子的数量和寿命。这些优越的特性使新开发的光电探测器适用于未来的多功能光电检测应用。
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来源期刊
2D Materials
2D Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
10.70
自引率
5.50%
发文量
138
审稿时长
1.5 months
期刊介绍: 2D Materials is a multidisciplinary, electronic-only journal devoted to publishing fundamental and applied research of the highest quality and impact covering all aspects of graphene and related two-dimensional materials.
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