W. Stillman scite author profile

We fabricated a large number of single and bilayer graphene transistors and carried out a systematic experimental study of their low-frequency noise characteristics. A special attention was given to determining the dominant noise sources in these devices and the effect of aging on the current-voltage and noise characteristics. The analysis of the noise spectral density dependence on the area of graphene channel showed that the dominant contributions to the low-frequency electronic noise come from the graphene layer itself rather than from the contacts. Aging of graphene transistors due to exposure to ambient for over a month resulted in substantially increased noise attributed to the decreasing mobility of graphene and increasing contact resistance. The noise spectral density in both single and bilayer graphene transistors either increased with deviation from the charge neutrality point or depended weakly on the gate bias. This observation confirms that the low-frequency noise characteristics of graphene transistors are qualitatively different from those of conventional silicon metal-oxide-semiconductor field-effect transistors. Electronic address: balandin@ee.ucr.edu ; group web-site: http://www.ndl

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Low-frequency electronic noise in the double-gate single-layer graphene transistors

Liu

et al. 2009

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The authors report the results of an experimental investigation of the low-frequency noise in the double-gate graphene transistors. The back-gate graphene devices were modified via addition of the top gate separated by ∼20 nm of HfO2 from the single-layer graphene channels. The measurements revealed low flicker noise levels with the normalized noise spectral density close to 1/f (f is the frequency) and Hooge parameter αH≈2×10−3. The analysis of noise spectral density dependence on the top and bottom gate biases helped to elucidate the noise sources in these devices. The obtained results are important for graphene electronic and sensor applications.

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Enhanced Plasma Wave Detection of Terahertz Radiation Using Multiple High Electron-Mobility Transistors Connected in Series

Elkhatib

Kachorovskii

Stillman

et al. 2010

IEEE Trans. Microwave Theory Techn.

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Terahertz response of field-effect transistors in saturation regime

Elkhatib

Kachorovskii²,

Stillman

et al. 2011

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Device loading effects on nonresonant detection of terahertz radiation by silicon MOSFETs

et al. 2007

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W. Stillman

Electrical and noise characteristics of graphene field-effect transistors: ambient effects, noise sources and physical mechanisms

Low-frequency electronic noise in the double-gate single-layer graphene transistors

Enhanced Plasma Wave Detection of Terahertz Radiation Using Multiple High Electron-Mobility Transistors Connected in Series

Terahertz response of field-effect transistors in saturation regime

Device loading effects on nonresonant detection of terahertz radiation by silicon MOSFETs

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