Experimental Demonstration of Improvement in Near-Infrared Photodetection Efficiency by Plasmonic Diffraction

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Soh Uenoyama, Kazunori Tanaka, Hiroyasu Fujiwara, Akiyoshi Watanabe, Atsushi Ono
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Abstract

Near-infrared (NIR) photodetectors are crucial to various applications, including face recognition, night vision, and laser detection and ranging (LiDAR). However, conventional silicon (Si)-based photodetectors exhibit poor sensitivity in the NIR region (λ = 750–1060 nm) because of low photoabsorption within the photoabsorption layer. To overcome this limitation, we proposed a plasmonic diffraction approach that can improve photosensitivity in the NIR regime by properly designing the period of the metal nanograting required to diffract the incident light at large angles in Si, thereby extending the effective propagation length in the photoabsorption layer. In addition, the metal nanograting can transmit the specific wavelength and polarization while enhancing photosensitivity through optimized geometric design. It can be highly advantageous for active sensing applications such as LiDAR, which offers the distinction between signal and noise by selectively transmitting specific wavelengths and polarizations. However, the effectiveness of plasmonic diffraction has never been experimentally demonstrated because it requires the fabrication of a metal nanograting structure with a fine gap. In this study, we successfully fabricated a gold nanograting array on a photodetector and demonstrated a significant improvement (1.79×) in its photosensitivity while employing it as a bandpass filter as well as a polarization filter, even with a single thin gold layer. In addition, providing highly reflective trenches at the border of each pixel will allow the diffracted light to be confined within the pixel, leading to the expansion of image sensors while increasing photosensitivity. This breakthrough will usher in further advances in nanophotonic devices that will enable the development of active sensing technologies with high signal-to-noise ratios.

Abstract Image

利用等离子衍射提高近红外光电探测效率的实验演示
近红外(NIR)光电探测器对人脸识别、夜视和激光探测与测距(LiDAR)等各种应用至关重要。然而,由于光吸收层内的光吸收率较低,传统的硅基光电探测器在近红外区域(λ = 750-1060 纳米)的灵敏度较低。为了克服这一局限性,我们提出了一种等离子衍射方法,通过适当设计入射光在硅中发生大角度衍射所需的金属纳米穿透周期,从而延长光吸收层中的有效传播长度,提高近红外区的光灵敏度。此外,通过优化几何设计,金属纳米蚀刻可以传输特定波长和偏振,同时提高光敏性。这对于主动传感应用(如激光雷达)非常有利,它通过选择性地传输特定波长和偏振来区分信号和噪声。然而,等离子体衍射的有效性还从未在实验中得到证实,因为它需要制造具有精细间隙的金属纳米孔隙结构。在这项研究中,我们成功地在一个光电探测器上制造了一个金纳米穿透阵列,并将其用作带通滤波器和偏振滤波器,即使只有一个薄金层,其光敏度也有显著提高(1.79 倍)。此外,在每个像素的边界提供高反射沟槽,可将衍射光限制在像素内,从而在提高感光度的同时扩大图像传感器的范围。这一突破将进一步推动纳米光子器件的发展,从而开发出具有高信噪比的主动传感技术。
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
CiteScore
7.20
自引率
4.30%
发文量
567
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