Your search keyword '"Chenming Calvin Hu"' showing total 2 results

1. 2D MOSFET operation of a fully-depleted bulk MoS2 at quasi-flatband back-gate

Author

Yuping Zeng, Juan Pablo Duarte, M. Najmzadeh, Sourabh Khandelwal, and Chenming Calvin Hu

Subjects

Electron mobility, Semiconductor, Materials science, Gate oxide, business.industry, MOSFET, Electrical engineering, Optoelectronics, Silicon on insulator, Equivalent oxide thickness, business, Capacitance, Subthreshold slope

Abstract

In this paper, 2D MOSFET operation of a fully-depleted double-gate bulk MoS 2 is studied at a quasi-flatband of the back-gate for the first time. Several key device parameters such as equivalent oxide thickness (EOT), carrier concentration, flatband voltage, dielectric constant and carrier mobility were extracted from I-V and C-V characteristics and at room temperature. In a similar operation to the inversion-mode SOI MOSFETs in [1], the backgate was used to keep a sheet of mobile charges on the flake back-side by its quasi-flatband operation at a fixed voltage (0 V). Afterward, the top-gate was used as the active gate to perform mobile charge accumulation or depletion in the channel. Fig. 1 shows the device architecture together with the high frequency R-C equivalent circuit model for this underlap gate architecture. Fig. 2 represents the top-view microscope picture of the fabricated MoS 2 bulk MOSFET with a flake thickness of 38 nm, measured by AFM. The fabrication steps include mechanical exfoliation of MoS 2 crystals on a 260 nm thick oxidized Si substrate, e-beam lithography to make S/D pads, 50 nm Ni by thermal evaporation and lift-off, gate patterning, high-k/metal-gate stack deposition (1 nm of SiO x by thermal evaporation, 11 nm of ZrO 2 by ALD deposition at 105 °C, 30 nm of Ni by thermal evaporation) and lift-off. The measurements were done at room temperature using an Agilent B1500A Semiconductor Parameter Analyzer. Fig. 3 shows its I d -V g , reporting a subthreshold slope of 110 mV/dec. and I on /I off of ∼1×105, both at V ds =100 mV.

Published

2015

2. A 60-nm-thick enhancement mode In0.65Ga0.35As/InAs/In0.65Ga0.35As high-electron-mobility transistor fabricated using Au/Pt/Ti non-annealed ohmic technology for low-power logic applications.

Author

Faiz Aizad Fatah, Yueh-Chin Lin, Ren-Xuan Liu, Kai-Chun Yang, Tai-We Lin, Heng-Tung Hsu, Jung-Hsiang Yang, Yasuyuki Miyamoto, Hiroshi Iwai, Chenming Calvin Hu, Sayeef Salahuddin, and Edward Yi Chang

Abstract

A 60-nm-thick E-mode In0.65Ga0.35As/InAs/In0.65Ga0.35As high-electron-mobility transistor (HEMT) was successfully fabricated and evaluated by using Au/Pt/Ti-based non-annealed ohmic technology for high-speed and low-power logic applications. The device exhibited a minimal SS of 69 mV/decade, a lower DIBL of 30 mV/V, an ION/IOFF ratio above 1.2 × 104 at VDS = 0.5 V and a high fT of 378 GHz and fmax of 214 GHz at VDS = 1.0 V. These results demonstrate that non-annealed ohmic contacts can be used for fabricating E-mode In0.65Ga0.35As/InAs/In0.65Ga0.35As HEMTs with excellent electrical characteristics. The fabricated HEMTs are likely to find use in future high-speed and low-power logic applications. [ABSTRACT FROM AUTHOR]

Published

2016