Dae-Myeong Geum, Jinha Lim, Junho Jang, Seungyeop Ahn, SeongKwang Kim, Joonsup Shim, Bong Ho Kim, Juhyuk Park, Woo Jin Baek, Jaeyong Jeong, SangHyeon Kim
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引用次数: 0
摘要
本文展示了亚微米厚 InGaAs 宽带光电探测器(PD)的新方法,该方法旨在实现从可见光到短波红外(SWIR)光谱的高分辨率成像。传统方法会遇到分辨率低和厚吸收层(AL)引起的串扰问题等挑战。因此,我们提出了一种导模共振(GMR)结构,以提高仅具有亚微米厚吸收层的 InGaAs PD 在 SWIR 区域的量子效率(QE)。基于 TiOx/Au 的 GMR 结构弥补了 AL 厚度的减少,在 400 纳米到 1700 纳米的范围内,仅用 0.98 μm AL InGaAs PD(定义为 1 μm AL PD)就实现了非常高的 QE(>70%)。与之前的结果相比,这意味着在保持高 QE 的同时,厚度至少减少了 2.5 倍。此外,快速传输时间有望减少电串扰。GMR 结构的有效性体现在,即使 AL 厚度减少,它仍能保持 QE,同时提高传输时间。这一突破为高分辨率和低噪声宽带图像传感器提供了可行的解决方案。
Highly-efficient (>70%) and Wide-spectral (400-1700 nm) sub-micron-thick InGaAs photodiodes for future high-resolution image sensors.
This paper demonstrates the novel approach of sub-micron-thick InGaAs broadband photodetectors (PDs) designed for high-resolution imaging from the visible to short-wavelength infrared (SWIR) spectrum. Conventional approaches encounter challenges such as low resolution and crosstalk issues caused by a thick absorption layer (AL). Therefore, we propose a guided-mode resonance (GMR) structure to enhance the quantum efficiency (QE) of the InGaAs PDs in the SWIR region with only sub-micron-thick AL. The TiOx/Au-based GMR structure compensates for the reduced AL thickness, achieving a remarkably high QE (>70%) from 400 to 1700 nm with only a 0.98 μm AL InGaAs PD (defined as 1 μm AL PD). This represents a reduction in thickness by at least 2.5 times compared to previous results while maintaining a high QE. Furthermore, the rapid transit time is highly expected to result in decreased electrical crosstalk. The effectiveness of the GMR structure is evident in its ability to sustain QE even with a reduced AL thickness, simultaneously enhancing the transit time. This breakthrough offers a viable solution for high-resolution and low-noise broadband image sensors.
期刊介绍:
Light: Science & Applications is an open-access, fully peer-reviewed publication.It publishes high-quality optics and photonics research globally, covering fundamental research and important issues in engineering and applied sciences related to optics and photonics.
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