| Title |
Modeling of antenna-coupled Si MOSFETs in the terahertz frequency range / |
| Authors |
Ludwig, Florian ; Holstein, Jakob ; Krysl, Anastasiya ; Lisauskas, Alvydas ; Roskos, Hartmut G |
| DOI |
10.1109/TTHZ.2024.3388254 |
| Full Text |
|
| Is Part of |
IEEE Transactions on terahertz science and technology.. Piscataway : IEEE Microwave Theory and Techniques Society. 2024, vol. 14, iss. 3, p. 414-423.. ISSN 2156-342X. eISSN 2156-3446 |
| Keywords [eng] |
antenna simulation ; detection ; Gaussian beam ; hydrodynamic ; mosfet ; power coupling ; Taiwan semiconductor manufacturing company (TSMC) ; terahertz (THz) |
| Abstract [eng] |
We report on the modeling and experimental characterization of Si complementary metal-oxide-silicon (CMOS) detectors of terahertz radiation based on antenna-coupled field-effect transistors (TeraFETs). The detectors are manufactured using Taiwan semiconductor manufacturing company (TSMC's) 65-nm technology. We apply two models - the TSMC RF foundry model and our own advanced design system (ADS)-hydrodynamic transport model (HDM) - to simulate the Si CMOS TeraFET performance and compare their predictions with respective experimental data. Both models are implemented in the commercial circuit simulation software keysight ADS. We find that the compact model TSMC RF is capable to predict the detector responsivity and its dependence on frequency and gate voltage with good accuracy up to the highest frequency of 1.2 THz covered in this study. This frequency is well beyond the tool's intended operation range for 5G communications and 110-GHz millimeter wave applications. We demonstrate that our self-developed physics-based ADS-HDM tool, which relies on an extended 1-D HDM and can be adapted readily to other material technologies, has high predictive qualities comparable to those of the foundry model. We use the ADS-HDM to discuss the contribution of diffusive and plasmonic effects to the THz response of Si CMOS TeraFETs, finding that these effects, while becoming more significant with rising frequency, are never dominant. Finally, we estimate that the electrical noise-equivalent power (perfect power coupling conditions) is on the order of 5 pW/sqrt{mathrm{Hz}} at room-temperature. |
| Published |
Piscataway : IEEE Microwave Theory and Techniques Society |
| Type |
Journal article |
| Language |
English |
| Publication date |
2024 |
| CC license |
|
