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Applied Physics 2025
不同光敏元尺寸对InGaAs探测器光电流的影响
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Abstract:
InGaAs光电探测器因其优异的短波红外响应特性、低暗电流和高响应度,在红外成像、激光通信和光谱检测等领域具有广泛应用。光敏元作为探测器的核心结构,其面积大小不仅影响光通量的吸收效率,还关系到器件的空间分辨率和光电性能。然而,光敏元面积对光电流特性的具体影响规律仍需系统实验验证。为此,本文设计并制备了光敏元面积从30 × 30 μm2至500 × 500 μm2的InGaAs探测器样品,测试并分析了其在暗态和光照条件下的电流–电压(I-V)特性。结果表明,随着光敏面积的增加,光电流呈明显增强趋势,且I-V曲线形状保持一致,反映出材料制程的一致性。在暗态下,暗电流随光敏元面积的增大而增大,但单位面积暗电流密度基本稳定,说明其主要来源为体电流。在光照条件下,不同面积器件的光电流接近线性增长,验证了光敏面积对光响应能力的直接影响。研究结果为InGaAs光电探测器在高分辨率与多像元集成应用中的结构设计提供了重要参考。
This InGaAs photodetector, with its excellent short-wavelength infrared response, low dark current, and high responsivity, has been widely applied in infrared imaging, laser communication, and spectral detection. As the core structure of the detector, the area of the photosensitive element not only affects the efficiency of light flux absorption but also relates closely to the spatial resolution and photoelectric performance of the device. However, the specific influence of the photosensitive area on photocurrent characteristics still requires systematic experimental verification. To this end, this study designs and fabricates InGaAs detector samples with photosensitive areas ranging from 30 × 30 μm2 to 500 × 500 μm2, and investigates their current-voltage (I-V) characteristics under both dark and illuminated conditions. The results show that as the photosensitive area increases, the photocurrent exhibits a significant rising trend, while the overall I-V curve shape remains consistent, reflecting the uniformity of the material fabrication process. Under dark conditions, the dark current increases with the photosensitive area, but the dark current density per unit area remains nearly constant, indicating that the primary source is bulk current. Under illumination, the photocurrent of devices with different areas increases nearly linearly, confirming the direct impact of the photosensitive area on light response capability. These findings provide valuable reference for structural design in high-resolution and multi-pixel integrated applications of InGaAs photodetectors.
| [1] | Choi, K., Oduor, P., Dhar, N.K. and Dutta, A.K. (2023) Resonant InGaAs Detectors and Emitters for Passive and Active Imaging Application. IEEE Journal of Quantum Electronics, 59, Article ID: 5000113. https://doi.org/10.1109/jqe.2022.3231260 |
| [2] | Jiao, J., Ji, R., Yao, L., Rao, Y., Ke, S., Xu, J., et al. (2024) InGaAs/Si PIN Photodetector with Low Interfacial Recombination Rates Realized by Wafer Bonding with a Polycrystalline Si Interlayer. Applied Physics Letters, 124, Article ID: 121101. https://doi.org/10.1063/5.0192394 |
| [3] | Mohammadnejad, S. and Aasi, M. (2023) Analysis of Structures and Technologies of Various Types of Photodetectors Used in Laser Warning Systems: A Review. Optical Engineering, 62, Article ID: 090901. https://doi.org/10.1117/1.oe.62.9.090901 |
| [4] | Song, B., Shi, B., Suran-Brunelli, S.T., Zhu, S. and Klamkin, J. (2022) Low Dark Current and High Speed InGaAs Photodiode on Cmos-Compatible Silicon by Heteroepitaxy. IEEE Journal of Selected Topics in Quantum Electronics, 28, 1-8. https://doi.org/10.1109/jstqe.2021.3123052 |
| [5] | Ye, Y., Ma, H., Wu, J., Sun, B., Jian, J., Wei, M., et al. (2024) Flexible InGaAs Photodetector with High-Speed Detection and Long-Term Stability. IEEE Journal of Selected Topics in Quantum Electronics, 30, Article ID: 3801308. https://doi.org/10.1109/jstqe.2024.3350431 |
| [6] | 崔星宇, 林逢源, 张志宏, 唐吉龙, 方铉, 房丹, 王登魁, 李科学, 魏志鹏. 低噪声InGaAs/Inp雪崩光电二极管的模拟分析[J]. 中国激光, 2021, 48(17): 10-16. |
| [7] | Zhang, J., Liu, A., Xing, H. and Yang, Y. (2022) Study on Surface Leakage Current at Sidewall in Inp-Based Avalanche Photodiodes with Mesa Structure. AIP Advances, 12, Article ID: 035336. https://doi.org/10.1063/5.0080656 |
| [8] | 李庆法. InGaAs探测器的光电性能仿真与结构优化研究[D]: [硕士学位论文]. 北京: 中国科学院大学, 2016. |
