Title :
Graphene FET-Based Zero-Bias RF to Millimeter-Wave Detection
Author :
Moon, J.S. ; Seo, H.-C. ; Antcliffe, M. ; Lin, S. ; McGuire, C. ; Le, D. ; Nyakiti, L.O. ; Gaskill, D.K. ; Campbell, P.M. ; Lee, K.-M. ; Asbeck, P.
Author_Institution :
HRL Labs. LLC, Malibu, CA, USA
Abstract :
We report direct radio-frequency (RF) and millimeter-wave detection of epitaxial graphene field-effect transistors (FETs) up to 110 GHz with no dc biases applied, leveraging the nonlinearity of the channel resistance. A linear dynamic range of >; 40 dB was measured, providing at least 20-dB greater linear dynamic range compared to conventional CMOS detectors at transistor level. The measured noise power of the graphene FETs was ~7.5 × 10-18 V2/Hz at zero bias and without 1/f noise. At a 50-Ω load, measured detection responsivity was 71 V/W at 2 GHz to 33 V/W at 110 GHz. The noise-equivalent power at 110 GHz was estimated to be ~80 pW/Hz0.5. For the first time, we demonstrated graphene FETs as zero-bias ultrawideband direct RF detectors with comparable or better performance than state-of-the-art FET-based detectors without dc biases applied.
Keywords :
1/f noise; CMOS analogue integrated circuits; field effect MIMIC; field effect transistors; graphene; millimetre wave detectors; 1/f noise; CMOS detectors; DC bias; FET-based detectors; channel resistance nonlinearity; detection responsivity; direct radiofrequency detection; epitaxial graphene FET-based zero-bias RF; epitaxial graphene field effect transistors; frequency 110 GHz; frequency 2 GHz; linear dynamic range; measured noise power; millimeter-wave detection; noise-equivalent power; transistor level; zero-bias ultrawideband direct RF detectors; Detectors; FETs; Logic gates; Noise; Power measurement; Radio frequency; Voltage measurement; Energy harvesting; field-effect transistor (FET); graphene; millimeter wave; power detector; radio-frequency identification (RFID); rectification;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2012.2210184
