Banpil Photonics has developed a novel InGaAs based photodetector array for Short-Wave Infrared (SWIR) imaging, for the most demanding security, defense, and machine vision applications. These applications require low noise from both the detector and the readout integrated circuit arrays. In order to achieve high sensitivity, it is crucial to minimize the dark current generated by the photodiode array. This enables the sensor to function in extremely low light situations, which enables it to successfully exploit the benefits of the SWIR band. In addition to minimal dark current generation, it is essential to develop photodiode arrays with higher operating temperatures. This is critical for reducing the power consumption of the device, as less energy is spent in cooling down the focal plane array (in order to reduce the dark current). We at Banpil Photonics are designing, simulating, fabricating and testing SWIR InGaAs arrays, and have achieved low dark current density at room temperature. This paper describes Banpil’s development of the photodetector array. We also highlight the fabrication technique used to reduce the amount of dark current generated by the photodiode array, in particular the surface leakage current. This technique involves the deposition of strongly negatively doped semiconductor material in the area between the pixels. This process reduces the number of dangling bonds present on the edges of each pixel, which prevents electrons from being swept across the surface of the pixels. This in turn drastically reduces the amount of surface leakage current at each pixel, which is a major contributor towards the total dark current. We present the optical and electrical characterization data, as well as the analysis that illustrates the dark current mechanisms. Also highlighted are the challenges and potential opportunities for further reduction of dark current, while maintaining other parameters of the photodiode array, such as size, weight, temperature of peak performance (lowest dark current), and power consumption.
[1]
E. Mounier,et al.
Microbolometers: a market perspective
,
2012,
Photonics West - Micro and Nano Fabricated Electromechanical and Optical Components.
[2]
Achyut K. Dutta,et al.
High performance broadband photodetector and its array for optical communication
,
2015,
Photonics West - Optoelectronic Materials and Devices.
[3]
Achyut K. Dutta,et al.
Novel optical nano-sensor for biomolecule and chemical agents detection
,
2005,
SPIE OPTO.
[4]
Saif Islam,et al.
Broadband image sensors for biomedical, security, and automotive applications
,
2007,
SPIE Optics East.
[5]
A. Rogalski.
Progress in focal plane array technologies
,
2012
.
[6]
Achyut K. Dutta,et al.
Effect of dense planer focal plane array on device performances
,
2014,
Sensing Technologies + Applications.
[7]
Ping Yuan,et al.
Low-dark current 1024×1280 InGaAs PIN arrays
,
2014,
Defense + Security Symposium.
[8]
Kenko Taguchi,et al.
P-I-N Photodiodes
,
2002
.
[9]
Achyut K. Dutta,et al.
Development of low-cost high-performance multispectral camera system at Banpil
,
2014,
Sensing Technologies + Applications.
[10]
Achyut K. Dutta,et al.
Novel nano-sensor for biomedical and industrial applications
,
2005,
SPIE Optics East.
[11]
Achyut K. Dutta,et al.
Novel multi-color image sensors for bio-chemical, bio-medical, and security applications
,
2005,
SPIE Optics East.