We present the design, fabrication, and characterization, of multi-spectral quantum dots-in-a-well (DWELL) infrared detectors, by the integration of a surface plasmon assisted resonant cavity with the infrared detector. A square lattice and rectangular lattice cavity, formed by modifying the square lattice have been used in this design. By confining the resonant mode of the cavity to detector active region, the detector responsivity and detectivity have been improved by a factor of 5. A spectral tuning of 5.5 to 7.2 μm has been observed in the peak response of the detectors, by tuning the lattice constant of the cavity. Simulations indicate the presence of two modes of absorption, which have been experimentally verified. The use of a rectangular lattice predicts highly polarization sensitive modes in x- and y-direction, which are observed in fabricated detectors. A peak detectivity of 3.1 x 10^9 cm √(Hz)/W was measured at 77 K. This design offers a cost-effective and simple method of encoding spectral and polarization information, in infrared focal plane arrays.
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机译:通过将表面等离子体激元辅助谐振腔与红外探测器集成在一起,我们介绍了多光谱井中量子点(DWELL)红外探测器的设计,制造和表征。通过修改正方形晶格形成的正方形晶格和矩形晶格腔已用于此设计中。通过将谐振腔的共振模式限制在检测器的活动区域,检测器的响应度和检测率提高了5倍。通过调整晶格,可以在检测器的峰值响应中观察到5.5至7.2μm的光谱调谐空腔常数。模拟表明存在两种吸收模式,已通过实验验证。矩形晶格的使用可预测在x和y方向上的高度偏振敏感模式,这在制造的探测器中可以观察到。在77 K时测得的峰值检测灵敏度为3.1 x 10 ^ 9 cm√(Hz)/ W。此设计提供了一种在红外焦平面阵列中编码光谱和偏振信息的经济有效且简单的方法。
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