Accumulation-mode GAA Si NW nFET with sub-5 nm cross-section and high uniaxial tensile strain

Author

Najmzadeh, Mohammad ; Bouvet, Didier ; Grabinski, Wladek ; Ionescu, Adrian M.

Author_Institution

Nanoelectronic Devices Lab., Swiss Fed. Inst. of Technol. (EPFL), Lausanne, Switzerland

fYear

2011

Firstpage

311

Lastpage

314

Abstract

In this work we report dense arrays of highly doped gate-all-around Si nanowire accumulation-mode nMOS-FETs with sub-5 nm cross-sections. The integration of local stressor technologies (both local oxidation and metal-gate strain) to achieve ≥2.5 GPa uniaxial tensile stress is reported for the first time. The deeply scaled Si nanowire shows low-field electron mobility of 332 cm²/V.s at room temperature, 32% higher than bulk mobility at the equivalent high channel doping. The conduction mechanism as well as high temperature performance was studied based on the electrical characteristics from room temperature up to ≈400 K and a V_TH drift of -1.72 mV/K, V_FB drift of -3.04 mV/K and an ion impurity scattering-based mobility reduction were observed.

Keywords

MOSFET; electron mobility; elemental semiconductors; impurity scattering; nanowires; silicon; Si; bulk mobility; electrical characteristics; equivalent high channel doping; gate-all-around nanowire accumulation-mode nMOSFET; high temperature performance; high uniaxial tensile stress; ion impurity scattering-based mobility reduction; local oxidation; local stressor technologies; low-field electron mobility; metal-gate strain; size 5 nm; temperature 293 K to 298 K; Logic gates; MOSFETs; Silicon; Temperature; Tensile stress; Threshold voltage; Tin;

fLanguage

English

Publisher

ieee

Conference_Titel

Solid-State Device Research Conference (ESSDERC), 2011 Proceedings of the European

Conference_Location

Helsinki

ISSN

1930-8876

Print_ISBN

978-1-4577-0707-0

Electronic_ISBN

1930-8876

Type

conf

DOI

10.1109/ESSDERC.2011.6044172

Filename

6044172