Modeling and Simulation of High-κ Gate GaSb Nanowire Field Effect Transistor for Ultra High Speed and Low Power Applications

Jahangir, Ifat; Jahangir, Shafat; Khosru, Quazi D. M.

doi:10.1149/1.3569905

Cited by 6 publications

(1 citation statement)

References 23 publications

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“…While 2D-2D and 2D-3D heterojunctions have become quite common in the recent years, the concept of graphene on one-dimensional (1D) structures, such as nanowires (NWs), nanotubes or nanorods is still relatively unexplored and may be of particular interest, as the high degree of quantum confinement occurring inside a 1D structure makes it very different from its 2D counterparts and bulk crystals [26][27][28][29][30][31]. In our earlier works, we have shown such exceptional behaviors of NWs, especially for III-V NWs with recent focus on planar InN NWs, which could be synthesized with high crystalline quality [31][32][33][34][35].…”

Section: Introductionmentioning

confidence: 99%

Electrically or chemically tunable photodetector with ultra high responsivity using graphene/InN nanowire based mixed dimensional barristors

et al. 2021

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In this work, an electrically/chemically tunable highly sensitive photodetector based on mixed dimensional heterojunction of graphene and planar InN nanowires (NW) is presented. Controlled partial oxidation of InN has been employed to effectively reduce the high surface carrier concentration of InN, which normally prevents it from forming good rectifying contact with graphene. The resulting surface modified InN NWs have been found to form excellent Schottky junction with graphene, with an increase in effective Schottky barrier height (SBH) by over 1.1 eV and a ratio of forward and reverse bias currents exceeding 4 orders of magnitude. Moreover, very strong barristor (gate tunable heterojunction) action has been observed, with I on/I off ≈ 4 orders of magnitude, and SBH increase by >0.3 eV. The barristor has been demonstrated to be highly sensitive to light, especially in the ultra-voilet, visible and near IR spectra. Responsivity was found to be widely tunable by gate voltage, with the highest value exceeding 1000 A W−1. Rise and fall times being in the range of hundreds of ms are indicative of photoconductive gain, which can be attributed to the ultra high responsivity. A method of semi-permanent molecular doping has been demonstrated to realize a two-terminal version of the photodetector, where the desired responsivity can still be achieved without requiring a back gate terminal, enabling the device to be realized on insulating substrates. The effect of encapsulation has been studied as a function of time, which has showed the long term stability of the dopant-induced enhancement and ultra high responsivity of the barristor photodetector.

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Section: Introductionmentioning

confidence: 99%

Electrically or chemically tunable photodetector with ultra high responsivity using graphene/InN nanowire based mixed dimensional barristors

et al. 2021

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Impact of high‐κ gate dielectric and other physical parameters on the electrostatics and threshold voltage of long channel gate‐all‐around nanowire transistor

Khan

Hossain

Rahman

et al. 2014

Int J Numerical Modelling

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High‐κ gate‐all‐around structure counters the Short Channel Effect (SCEs) mostly providing excellent off‐state performance, whereas high mobility III–V channel ensures better on‐state performance, rendering III–V nanowire GAAFET a potential candidate for replacing the current FinFETs in microchips. In this paper, a 2D simulator for the III–V GAAFET based on self‐consistent solution of Schrodinger–Poisson equation is proposed. Using this simulator, capacitance–voltage profile and threshold voltage are characterized, which reveal that gate dielectric constant (κ) and oxide thickness do not affect threshold voltage significantly at lower channel doping. Moreover, change in alloy composition of InxGa1‐xAs, channel doping, and cross‐sectional area has trivial effects on the inversion capacitance although threshold voltage can be shifted by the former two. Although, channel material also affects the threshold voltage, most sharp change in threshold voltage is observed with change in fin width of the channel (0.005 V/nm for above 10 nm fin width and 0.064 V/nm for sub‐10 nm fin width). Simulation suggests that for lower channel doping below 1023 m−3, fin width variation affects the threshold voltage most. Whereas when the doping is higher than 1023 m−3, both the thickness and dielectric constant of the oxide material have strong effects on threshold voltage (0.05 V/nm oxide thickness and 0.01 V/per unit change in κ). Copyright © 2014 John Wiley & Sons, Ltd.

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Investigation of graphene/InN nanowire based mixed dimensional barristors with widely tunable Schottky barrier for highly sensitive multimodal gas sensing applications

Jahangir

Uddin

Franken

et al. 2023

Sensors and Actuators B: Chemical

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Modeling and Simulation of High-κ Gate GaSb Nanowire Field Effect Transistor for Ultra High Speed and Low Power Applications

Cited by 6 publications

References 23 publications

Electrically or chemically tunable photodetector with ultra high responsivity using graphene/InN nanowire based mixed dimensional barristors

Electrically or chemically tunable photodetector with ultra high responsivity using graphene/InN nanowire based mixed dimensional barristors

Impact of high‐κ gate dielectric and other physical parameters on the electrostatics and threshold voltage of long channel gate‐all‐around nanowire transistor

Investigation of graphene/InN nanowire based mixed dimensional barristors with widely tunable Schottky barrier for highly sensitive multimodal gas sensing applications

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