Abstract:
This paper presents different configurations of bilayer graphene (BLG)/mercury cadmium telluride (Hg1–xCdxTe) based GBn detectors operating in the mid- and long-wave infrared (IR) regime.
One type of configuration consists of a contact graphene layer (G) of p+-BLG and a barrier layer
(B) of p–
-Hg1–xCdx = 0.41Te deposited on the n+-Hg1–xCdxTe absorber layer (n) and is named as p+-
p–
-n+ detector. In another configuration, the n+-BLG contact layer and n–
-Hg1–xCdx = 0.41Te
barrier layer are deposited on n+-Hg1–xCdxTe absorber layer and is called a n+-n–
-n+ unipolar
detector. The Silvaco Atlas TCAD software is used for the optoelectronic characterizations which
closely matches the results obtained through analytical modeling. The proposed GBn detectors
demonstrate about 106 times improvement in photocurrent density and self-powered mode
operation. The proposed detectors demonstrate rapid photoswitching time <0.1 ps. The external
quantum efficiency (QEext) of 26.06, 11.68, 54.08, and 50.53% are found for p+-p–
-n+ mid-wave,
p+-p–
-n+ long-wave, n+-n–
-n+ mid-wave, and n+-n–
-n+ long-wave IR detectors, respectively, at
− 0.5 V and 77 K. Such detection performances are ascribed to the huge built-in electric field at
contact/barrier heterojunction, and large barrier height in conduction band resulting in enhanced
photogenerated carriers which contributes to the net photocurrent. Further, it is shown that the
multiplication effect of carriers in BLG and high electric field across the interface results in the
QEext >100% at near room temperature.
