超薄ii型量子阱和光子捕获结构实现了高效高温操作的近红外传感器

Amita Rawat, Anthony M. Chiu, K. Choi, Patrick Oduor, A. Dutta, M. Islam
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引用次数: 0

摘要

本文提出了一种基于多量子阱(MQW)的光电探测器设计方法,其波长选择范围为1-3 μm。我们展示了基于iii - v的嵌入光子捕获(PT)表面结构的ii型MQW堆栈的吸收系数和功率吸收剖面调制。我们提出了一种基于MQW的光电探测器设计空间,通过改变MQW的堆叠周期,阱和势垒尺寸分别为100-200 nm和5-10 nm。我们发现,在固定的波长灵敏度范围内,MQW的功率吸收增加。然而,阱和势垒尺寸的变化有利于波长灵敏度范围调制。波长选择性的上界为3 μm,可通过调节阱/势垒宽度实现。我们进一步提出了一种改进的器件结构,将较低波长的光信号封顶在1 μm。通过在MQW结构中引入光子捕获孔,我们还显示了功率吸收的巨大增加。最后,我们使用FDTD框架中生成的功率吸收曲线提取MQW的有效吸收系数,以显示所需的波长选择性。最后,我们利用提取的吸收系数进行了基于comsol的模拟,结果表明,引入光子捕获孔后,MQW探测器的量子效率提高了31%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Near-infrared sensors for high efficiency and high-temperature operation enabled by ultra-thin type-II quantum wells and photon-trapping structures
We present a multi-quantum well (MQW)-based photodetectors design method for a 1-3 μm wavelength selectivity range using the finite difference time domain (FDTD) Lumerical platform. We demonstrate absorption coefficient and power absorption profile modulation in an III-V-based type-II MQW stack embedded with photon-trapping (PT) surface structures. We present an MQW-based photodetectors design space by varying the MQW stacking period, and the well and the barrier dimensions from 100-200 and 5-10 nm respectively. We show that the power absorption in the MQW increases for a fixed wavelength sensitivity range. However, the well and the barrier dimension variation facilitate the wavelength sensitivity range modulation. The upper bound of 3 μm on the wavelength-selectivity is achieved by tuning the well/barrier widths. We further proposed a modified device structure to cap the lower wavelength optical signal and cap them at 1 μm. We also show a tremendous increase in power absorption by introducing photon-trapping holes into the MQW structure. Finally, we extract the effective absorption coefficient of the MQW using the power absorption profile generated in the FDTD framework to show the desired wavelength selectivity. Finally, we utilize the extracted absorption coefficient to perform a COMSOL-based simulation to show a 31% enhancement in quantum efficiency of the MQW detector with the introduction of photon-trapping holes.
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