Title :
Low-Frequency Noise of a Ballistic Rectifier
Author :
Singh, A.K. ; Kasjoo, Shahrir R. ; Song, A.M.
Author_Institution :
Sch. of Electr. & Electron. Eng., Univ. of Manchester, Manchester, UK
Abstract :
A ballistic-electron transport-based semiconductor nanorectifier, also known as a ballistic rectifier, has been demonstrated to have an intrinsic zero threshold voltage. In this paper, we characterize its low-frequency noise properties and show that the zero-threshold property enables elimination of the flicker noise. As a potential terahertz detector, the ballistic rectifier exhibits a noise equivalent power in the range of commercially available, uncooled thermal terahertz detectors. The observed noise in the device at finite biases is modeled quantitatively. The derived simple formula reveals that the narrowest part of the electron channels has a dominant role in the device noise properties.
Keywords :
ballistics; electron transport theory; flicker noise; power semiconductor devices; rectifiers; semiconductor device noise; submillimetre wave detectors; temperature sensors; terahertz wave detectors; ballistic-electron transport-based semiconductor nanorectifier; electron channel; flicker noise elimination; intrinsic zero threshold voltage property; low-frequency noise property; potential terahertz detector; uncooled thermal terahertz detector; Educational institutions; Frequency measurement; Microwave measurement; Noise; Noise measurement; Rectifiers; Temperature measurement; Ballistic rectifier; ballistic transport; low-frequency noise; microwave detector; terahertz;
Journal_Title :
Nanotechnology, IEEE Transactions on
DOI :
10.1109/TNANO.2014.2308593
