论文信息 - Modeling of LWIR nBn HgCdTe photodetector

Modeling of LWIR nBn HgCdTe photodetector

The nBn structure with an electron barrier sandwiched by n-type cap and absorber layers was predicted to suppress the Shockley-Read-Hall (SRH) generation-recombination processes and surface leakage. The MCT nBn structure has been studied by several groups to implement high operating temperature (HOT) device. In this report, the numerical analysis of the Hg1-xCdxTe nBn device in LWIR region (x=0.225) is performed utilizing Crosslight APSYS. The detector performance characterized by dark current, photo-current and detectivity is optimized by adjusting structural parameters such as Cd component and doping of each layer under various biases. Among the parameters, the trade-off between ΔEc and ΔEv is most intensively affected by Cd component of the barrier which was modified carefully and accomplished firstly. Furthermore, the effect of the trap density and trap energy level on the device performance is also investigated especially according to the processing techniques. At 110K, the optimized detectivity of the LWIR MCT nBn device reaches 7.5×1010 cmHz1/2/W in this report, comparable with that of the DLPH device (7.6×1010 cmHz1/2/W). The novel nBn HgCdTe structure is potentially valuable in LWIR region since the controllable p-doping issue is circumvented and passivation process is simplified.

[1] G. Wicks,et al. nBn detector, an infrared detector with reduced dark current and higher operating temperature , 2006 .

[2] Silviu Velicu,et al. Theoretical and experimental investigation of MWIR HgCdTe nBn detectors , 2012, OPTO.

[3] Jamie D. Phillips,et al. Design of an Auger-Suppressed Unipolar HgCdTe NBνN Photodetector , 2012, Journal of Electronic Materials.

[4] Piotr Martyniuk,et al. Theoretical modelling of MWIR thermoelectrically cooled nBn HgCdTe detector , 2013 .

[5] Jamie D. Phillips,et al. Design and Modeling of HgCdTe nBn Detectors , 2011 .

[6] H. S. Kim,et al. nBn structure based on InAs /GaSb type-II strained layer superlattices , 2007 .

[7] A. Rogalski. Infrared detectors: status and trends , 2003 .

[8] A. Kębłowski,et al. High-operating temperature MWIR nBn HgCdTe detector grown by MOCVD , 2013 .

[9] M. Kopytko,et al. Numerical Analysis of Current–Voltage Characteristics of LWIR nBn and p-on-n HgCdTe Photodetectors , 2013, Journal of Electronic Materials.

[10] Jamie D. Phillips,et al. Mid-wave infrared HgCdTe nBn photodetector , 2012 .

[11] Piotr Martyniuk,et al. HOT infrared photodetectors , 2013 .