FDSOI CMOS devices featuring dual strained channel and thin BOX extendable to the 10nm node

Al-Ameri

IEEE Trans. Electron Devices

et al. 2015

Abstract-In this paper, we have studied the impact of quantum confinement on the performance of n-type silicon nanowire transistors (NWTs) for application in advanced CMOS technologies. The 3-D drift-diffusion simulations based on the density gradient approach that has been calibrated with respect to the solution of the Schrödinger equation in 2-D cross sections along the direction of the transport are presented. The simulated NWTs have cross sections and dimensional characteristics representative of the transistors expected at a 7-nm CMOS technology. Different gate lengths, cross-sectional shapes, spacer thicknesses, and doping steepness were considered. We have studied the impact of the quantum corrections on the gate capacitance, mobile charge in the channel, drain-induced barrier lowering, and subthreshold slope. The mobile charge to gate capacitance ratio, which is an indicator of the intrinsic speed of the NWTs, is also investigated. We have also estimated the optimal gate length for different NWT design conditions.

mentioning

confidence: 99%

Simulation Study of the Impact of Quantum Confinement on the Electrostatically Driven Performance of n-type Nanowire Transistors

Al-Ameri

IEEE Trans. Electron Devices

et al. 2015

“…The degradation of the intrinsic FinFET transistor performance should not be surprising due to diminishing effectiveness of strain and increase of parasitic resistance in highly scaled FinFET. Contrary to the common misconception, high performance FDSOI devices have been demonstrated by using intrinsically strained channels, i.e., tensily strained silicon for NFET and compressively strained SiGe for PFET [30,32,59]. As shown in Figures 10 and 11, at V DD = 0.9 V and I OFF = 100 nA/µm, I EFF is 820 µA/µm and 615 µA/µm for NFET and PFET, respectively.…”

Section: High Performance Fdsoimentioning

confidence: 99%

Fully depleted SOI (FDSOI) technology

Cheng¹,

Khakifirooz

2016

Sci. China Inf. Sci.

IEEE Electron Device Lett.

“…In recent years, there has been a huge interest in the study and the modelling of the impact of material and geometrical features of Gate-all-around (GAA) nanowire transistors (NWTs) [1]- [5]. They are being considered as potential candidates to extend the CMOS technology beyond the 7 nm node [6] due to the better electrostatic integrity compared to Fully-Depleted Silicon-On-Insulator (FDSOI) [7] transistors and FinFETs [8]. To underpin these technology projections, it is important to study the impact of the NWT cross-sectional shape at the scaling limit on the transistor performance.…”

Section: Introductionmentioning

confidence: 99%

Mobility of Circular and Elliptical Si Nanowire Transistors Using a Multi-Subband 1D Formalism

Medina-Bailón

Sadi

Nedjalkov

et al. 2019

We have studied the impact of the cross-sectional shape on the electron mobility of n-type silicon nanowire transistors (NWTs). We have considered circular and elliptical cross-section NWTs including the most relevant multisubband scattering processes involving phonon, surface roughness, and impurity scattering. For this purpose, we use a flexible simulation framework, coupling 3D Poisson and 2D Schrödinger solvers with the semi-classical Kubo-Greenwood formalism. Moreover, we consider cross-section dependent effective masses calculated from tight binding simulations. Our results show significant mobility improvement in the elliptic NWTs in comparison to the circular one for both [100] and [110] transport directions, especially when surface roughness scattering is included.