Quantum Transport in a Silicon Nanowire FET Transistor: Hot Electrons and Local Power Dissipation

Martı́nez, Antonio; Barker, John R.

doi:10.3390/ma13153326

Cited by 8 publications

(4 citation statements)

References 110 publications

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“…Horiguchi et al [ 31 ] have discussed the Silicon nanowire bandgap dependency on the wire width using effective mass theory calculations and using the boundary conditions envelope between wire confinement potential and the barrier height confinement potential’s finiteness. Several authors have presented nanoscale modeling using green’s function, quantum transport modeling, density matrix calculation, and analyzing electronic devices in equilibrium conditions [ 32 , 33 , 34 , 35 ].…”

Section: Basics Of Negf Modelingmentioning

confidence: 99%

Design and Analysis of Gallium Arsenide-Based Nanowire Using Coupled Non-Equilibrium Green Function for RF Hybrid Applications

2023

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This research work uses sp3d5s* tight-binding models to design and analyze the structural properties of group IV and III-V oriented, rectangular Silicon (Si) and Gallium Arsenide (GaAs) Nanowires (NWs). The electrical characteristics of the NWs, which are shielded with Lanthanum Oxide (La2O3) material and the orientation with z [001] using the Non-Equilibrium Green Function (NEGF) method, have been analyzed. The electrical characteristics and the parameters for the multi-gate nanowires have been realized. A nanowire comprises a heavily doped n+ donor source and drains doping and n-donor doping at the channel. The specified nanowire has a gate length and channel length of 15 nm each, a source-drain device length LSD = 35 nm, with La2O3 as 1 nm (gate dielectric oxide) each on the top and bottom of the core material (Si/GaAs). The Gate-All-Around (GAA) Si NW is superior with a high (ION/IOFF ratio) of 1.06 × 109, and a low leakage current, or OFF current (IOFF), of 3.84 × 10−14 A. The measured values of the mid-channel conduction band energy (Ec) and charge carrier density (ρ) at VG = VD = 0.5 V are −0.309 eV and 6.24 × 1023 C/cm3, respectively. The nanowires with hydrostatic strain have been determined by electrostatic integrity and increased mobility, making them a leading solution for upcoming technological nodes. The transverse dimensions of the rectangular nanowires with similar energy levels are realized and comparisons between Si and GaAs NWs have been performed.

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Section: Basics Of Negf Modelingmentioning

confidence: 99%

Design and Analysis of Gallium Arsenide-Based Nanowire Using Coupled Non-Equilibrium Green Function for RF Hybrid Applications

2023

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“…What we have omitted so far is a discussion on heat transfer and potential thermoelectric effects which accompanies electron transport. For more background on this topic, the reader is referred to [238,279,378,379].…”

Section: Heat Transfer and Thermoelectric Systemsmentioning

confidence: 99%

Computational perspective on recent advances in quantum electronics: from electron quantum optics to nanoelectronic devices and systems

Weinbub

Kosik

2022

J. Phys.: Condens. Matter

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Quantum electronics has significantly evolved over the last decades. Where initially the clear focus was on light-matter interactions, nowadays approaches based on the electron's wave nature have solidified themselves as additional focus areas. This development is largely driven by continuous advances in electron quantum optics, electron based quantum information processing, electronic materials, and nanoelectronic devices and systems. The pace of research in all of these areas is astonishing and is accompanied by substantial theoretical and experimental advancements. What is particularly exciting is the fact that the computational methods, together with broadly available large-scale computing resources, have matured to such a degree so as to be essential enabling technologies themselves. These methods allow to predict, analyze, and design not only individual physical processes but also entire devices and systems, which would otherwise be very challenging or sometimes even out of reach with conventional experimental capabilities. This review is thus a testament to the increasingly towering importance of computational methods for advancing the expanding field of quantum electronics. To that end, computational aspects of a representative selection of recent research in quantum electronics are highlighted where a major focus is on the electron's wave nature. By categorizing the research into concrete technological applications, researchers and engineers will be able to use this review as a source for inspiration regarding problem-specific computational methods.

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“…Scaling down the transistors enables not only smaller chip area consumption but also has other benefits, such as decreasing the propagation delays in digital circuits and systems. However, scaling to the nanometer regime has always faced short channel effects, such as hot electrons, drain-induced barrier lowering (DIBL), threshold voltage roll-off, and so on [6,7]. In addition, channel pinch-off causes the drain current to be saturated.…”

Section: Introductionmentioning

confidence: 99%

Performance and Geometry Study of Silicon Nanowire-based Field Effect Diodes (FED)

GolshanBafghi

2023

JCHAR

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Nanostructured solid-state devices demonstrate prominent electronic transport properties and thus represent powerful building blocks for a wide range of analog and digital integrated circuits and systems. In this study, the integration of the side-contacted field effect diode (S-FED) with the silicon nanowire concept is pursued to create a device that maintains a substantial aspect ratio while delivering suitable execution. The nanowire side-contacted FED (NW-SFED), referred to as this apparatus, exhibits the capability to achieve an exceptionally high ON/OFF current ratio of 4×10 8 , allowing for efficient switching between ON and OFF states. While the downscaling of the planar CMOS technology has faced severe constraints, this characteristic is featured as a figure of merit for the NW-SFED device. Accordingly, the device can also be used in a coordinated device-circuit co-design framework as a promising candidate to mitigate noise, delay, and energy. Herein, a quantitative evaluation of NW-SFED's performance is conducted utilizing a semiconductor drift-diffusion solver to explore how variations in channel length, device width, as well as the dimensions of the n + and p + doped regions in the source and drain, respectively, influence its operational characteristics. The impact of the channel length, spacer length and device width on NW-SFED fabrication turned out to be negligible. In contrast, the thickness of doped regions emerged as the critical parameter in the fabrication process.

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Quantum Transport in a Silicon Nanowire FET Transistor: Hot Electrons and Local Power Dissipation

Cited by 8 publications

References 110 publications

Design and Analysis of Gallium Arsenide-Based Nanowire Using Coupled Non-Equilibrium Green Function for RF Hybrid Applications

Design and Analysis of Gallium Arsenide-Based Nanowire Using Coupled Non-Equilibrium Green Function for RF Hybrid Applications

Computational perspective on recent advances in quantum electronics: from electron quantum optics to nanoelectronic devices and systems

Performance and Geometry Study of Silicon Nanowire-based Field Effect Diodes (FED)

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