Vertical field enhanced nanostructure for quantum well infrared photodetector through Germanium subwavelength arrays

Wei Dong, T. Hirohata, K. Nakajima, Xiao-ping Wang
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Abstract

Finite-difference-time-domain (FDTD) computer simulations reveal interesting features of Germanium (Ge) subwavelength nanostructures designed in x-y plane on substrate of InP with normal incidence, which can be applied in quantum well infrared photodetector (QWIP). Unlike the mechanism of excellent near field effects through periodic metallic nanostructures, large intensity of Ez field is achieved at near-infrared range by subwavelength arrays of Ge which has no surface plasmons (SPs). The evanescent Ez field generated along the surface of Ge is interpreted due to waveguide mode interference of coupled scattering. The existence of the enhanced field is confirmed by comparing the Fourier transform infrared (FTIR) spectra of real-fabricated samples with simulation outcomes. Positions of resonant peaks obtained in experiment are in good agreement with those of simulation.
基于锗亚波长阵列的量子阱红外光电探测器垂直场增强纳米结构
时域有限差分(FDTD)计算机模拟揭示了在正入射InP衬底上在x-y平面上设计的锗(Ge)亚波长纳米结构的有趣特性,该结构可用于量子阱红外光电探测器(QWIP)。与周期性金属纳米结构的优异近场效应机制不同,在近红外范围内,通过不含表面等离子体(SPs)的Ge亚波长阵列实现了大强度的Ez场。对沿锗表面产生的倏逝Ez场进行了解释,认为这是由于耦合散射的波导模式干涉。通过将实际制备样品的傅里叶变换红外光谱与仿真结果进行比较,证实了增强场的存在。实验得到的共振峰位置与仿真结果吻合较好。
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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