Background limited infrared hot-electron transistor at 77K

51st Annual Device Research Conference Pub Date : 1900-01-01 DOI:10.1109/DRC.1993.1009624

C. Kuan, D. Tsui, K. Choi, W. Chang, C. Chang, C. Farley

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Abstract

The dominant noise of a quantum well infrared photodetector (QWIP) is from the dark current density (JD) and the background photocurrent density (JB). The optimal detector is a background limited photodetector (BLIP, i.e. JB >> JD). For practical applications, the total current density (= JB+JD) must be compatible with the charge handling capacity of the read-out circuit.' The desirable operating temperature of the detector for thermal imaging is 77K. We report a BLIP infrared hot-electron transistor (IHET) with current density compatible with the read-out circuit at 77K. To reduce JD, we have designed a new GaAs/Al,Gal_,As QWIP, in which the aluminum molar ratio of the barriers increases in three steps. This barrier is able to suppress the dark current due to thermally assisted tunneling by providing a thicker effective barrier when the structure is under bias. The remaining J D is also largely eliminated by designing a band pass filter placed adjacent to the QWIP. The IHET is grown by MBE in the following sequence: Emitter -6000-A n' GaAs ( 1 . 2 ~ 1 0 ' ~ ~ m ~ ) ; QWIP -30 periods of 50-A nf-GaAs quantum well (1 .2x101' ~ m ~ ) , and three-step Al,Gal_,As barrier (x=0.28, 0.305, and 0.33; thickness: 161 A, 167 A, and 173 A); Base -300-A n+ Ino.ljGao.8;As and 200-A n+ GaAs ( 1 . 0 ~ 1 0 ' ~ ~ m ~ ) ; Energy band pass filter -40-A Alo.3Gao.~As, 50-A GaAs, 40-8, Alo.3Gao.~As, and 1999-A Alo.25Gao.85As; Collector -1 . l-pm nf GaAs ( 1 . 2 ~ 1 0 ' ~ ~ m ~ ) . At 77K, with VBE up to 2V, the dark current afetr filtering is a t least 10' times smaller than that of the typical QWIP. At VBE = 2V, JD is approximately equal to JB and is within the current limit of the read-out circuit, and %BLIP (= noise current due to JB / total noise current) is 70% under a high photon flux background. The detectivity, Dc* (after filtering) is measured to be 1.0~10'0 c m m / W . At lower bias, Dc* increases and at VBE = l V , Dc8 is

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背景限制红外热电子晶体管在77K

量子阱红外探测器(QWIP)的主要噪声来自暗电流密度(JD)和背景光电流密度(JB)。最优的探测器是背景受限光电探测器(BLIP，即JB >> JD)。在实际应用中，总电流密度(= JB+JD)必须与读出电路的电荷处理能力相兼容。探测器用于热成像的理想工作温度为77K。我们报道了一种BLIP红外热电子晶体管(IHET)，其电流密度与读出电路在77K时兼容。为了降低JD，我们设计了一种新的GaAs/Al,Gal_，As QWIP，其中铝的摩尔比分三步增加。当结构处于偏置状态时，这种势垒能够通过提供更厚的有效势垒来抑制由于热辅助隧穿而产生的暗电流。通过在QWIP附近设计一个带通滤波器，剩余的jd也在很大程度上消除了。IHET由MBE按以下顺序生长:发射极-6000-A n' GaAs(1。2 ~ 10′~ ~ m ~);QWIP -30周期的50-A nf-GaAs量子阱(1.2 x101’~ m ~)和三阶Al、Gal_、As势垒(x=0.28、0.305和0.33;厚度:161a、167a、173a);碱-300-A n+ no. ljga8;As和200-A n+ GaAs(1。0 ~ 1 0′~ ~ m ~);带通滤波器- 40a alo3高。~As, 50-A - GaAs, 40-8, alo3 gao。~As，和1999-A alo25 ga85 As;收集器-1。l-pm nf GaAs (1;2 ~ 10′~ ~ m ~)。在77K时，VBE高达2V，滤波后的暗电流比典型的QWIP至少小10倍。在VBE = 2V时，JD约等于JB，且在读出电路的电流限制范围内，在高光子通量背景下，%BLIP(由JB引起的噪声电流/总噪声电流)为70%。检测率Dc*(滤波后)为1.0~10 cm m / W。在低偏置下，Dc*增大，在VBE = l V时，Dc8为

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51st Annual Device Research Conference

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