Resonant tunneling quantum dot infrared photodetector (RT-QDIP): separating dark current and photocurrent

Conference Digest [Includes 'Late News Papers' volume] Device Research Conference, 2004. 62nd DRC. Pub Date : 2004-06-21 DOI:10.1109/DRC.2004.1367793

X. Su, A. Stiff-Roberts, S. Chakrabarti, J. Singh, P. Bhattacharya

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Abstract

In this paper, we present a novel approach to reduce dark current in quantum dot infrared photodetectors that uses resonant tunneling barriers to selectively block dark current while transmitting photocurrent. In such a device, carriers in the quantum dots (QD) are resonantly excited by an IR photon and they tunnel through a double AlGaAs barrier to be collected as photocurrent. This double barrier, which acts as a resonant tunneling filter, is located between adjacent QD layers. When the double AlGaAs barrier thickness and position are properly designed, the electron tunneling probability is /spl sim/1 at a particular energy, corresponding to the desired peak detection wavelength. At the same time, the tunneling probability is several orders of magnitude lower for energies that are tens of meV removed from the peak energy. Thus, the dark current which results from electrons with a broad energy distribution, will be significantly reduced by the resonant tunneling filter.

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共振隧道量子点红外光电探测器(RT-QDIP):分离暗电流和光电流

在本文中，我们提出了一种减少量子点红外探测器暗电流的新方法，即在传输光电流时使用共振隧道势垒选择性地阻断暗电流。在这种装置中，量子点(QD)中的载流子被红外光子共振激发，它们穿过双AlGaAs势垒以光电流的形式被收集。这种双势垒，作为一个共振隧道滤波器，位于相邻的量子点层之间。当双AlGaAs势垒厚度和位置设计合理时，在特定能量下的电子隧穿概率为/spl sim/1，对应于期望的峰值探测波长。与此同时，距离峰值能量几十兆电子伏特的能量，隧穿概率要低几个数量级。因此，由具有广泛能量分布的电子产生的暗电流将被谐振隧道滤波器显著地减少。

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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Conference Digest [Includes 'Late News Papers' volume] Device Research Conference, 2004. 62nd DRC.

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