Abstract
This article reports on the investigation and optimization of cryogenic noise mechanisms in InGaAs metamorphic high-electron-mobility transistors (mHEMTs). HEMT technologies with a gate length of 100, 50, and 35 nm are characterized both under room temperature and cryogenic conditions. Furthermore, two additional technology variations with 50-nm gate length are investigated to decompose different noise mechanisms in HEMTs. Therefore, cryogenic extended Ku-band low-noise amplifiers of the investigated technologies are presented to benchmark their noise performance. Technology C with a 50-nm gate length exhibits an average effective noise temperature of 4.2 K between 8 and 18 GHz with a minimum of 3.3 K when the amplifier is cooled to 10 K. The amplifier provides an average gain of 39.4 dB at optimal noise bias. The improved noise performance has been achieved by optimization of the epitaxial structure of the 50-nm technology, which leads to low gate leakage currents and high gain at low drain current bias. To the best of the authors' knowledge, this is the first time that an average noise temperature of 4.2 K has been demonstrated in the Ku-band.
Highlights
O PTIMIZING for low noise in electronic receiver systems has a long tradition in microwave engineering because noise caused by electronics mainly limits the sensitivity of the receiver
The results shown in this article are based on metamorphic high-electron-mobility transistors (HEMTs) (mHEMTs) technologies with different gate lengths developed at Fraunhofer IAF
An investigation of mechanisms causing noise in mHEMTs at cryogenic conditions is shown. mHEMTs of different gate length and epitaxial structures have been investigated to separate the origin of effects influencing the noise temperature at cryogenic conditions
Summary
O PTIMIZING for low noise in electronic receiver systems has a long tradition in microwave engineering because noise caused by electronics mainly limits the sensitivity of the receiver. At microwave frequencies, it is, feasible to cool the receiver front end to cryogenic temperatures to reduce the impact of thermal noise. Beside this classical cryogenic application, readout circuits for quantum computing systems require the lowest noise temperatures in the low gigahertz regime. This is not feasible for the readout circuit since cooling power at deep cryogenic temperatures is limited to a few microwatts. HEINZ et al.: 50-nm GATE-LENGTH METAMORPHIC HEMT TECHNOLOGY OPTIMIZED FOR CRYOGENIC ULTRA-LOW-NOISE OPERATION the different epitaxial structures.
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