Journals & Magazines >IEEE Transactions on Electron... >Volume: 49 Issue: 9

Ultrathin gate oxide CMOS on [111] surface-oriented Si substrate

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Abstract:

The properties of ultrathin gate oxides in the direct-tunneling regime and the characteristics of the related CMOS transistors on a [111] surface-oriented Si substrate we...Show More

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Abstract:

The properties of ultrathin gate oxides in the direct-tunneling regime and the characteristics of the related CMOS transistors on a [111] surface-oriented Si substrate were investigated and compared with those on a [100] substrate for the first time. It was confirmed that low field mobility of n-MOSFETs on the [111] substrate is smaller than that on the [100] substrate and that of p-MOSFETs on [111] is larger than that on [100] until the direct-tunneling gate oxide regime. It has been found that most of the electrical properties of MOSFETs, with the notable exception of mobility, become almost identical for [100] and [111] substrates when the oxide thickness is reduced to less than 2.0 nm. Some of the properties are quite different between the two substrates for the thicker oxide case. It has been found that the reliability of hot carrier injection and time-dependent dielectric breakdown (TDDB) of the oxides and MOSFETs on the [111] substrate is slightly better than that on the [100] substrate. In addition, the characteristics and reliability of oxides and MOSFETs on a wafer tilted 4/spl deg/ from [100] axis were investigated. It was found that there are few differences in the mobility between [100] and [100] 4/spl deg/ off substrates for both n- and p-MOSFET cases. The reliability of oxides or MOSFETs on the wafer was identical to that on normal [100] substrate. These results suggest that ultrathin gate oxide MOSFETs on Si surfaces with various orientations are likely to have practical applications. This is good news for possible future new structures of MOSFETs such as vertical or three-dimensional (3-D) MOSFETs.

Published in: IEEE Transactions on Electron Devices ( Volume: 49, Issue: 9, September 2002)

Page(s): 1597 - 1605

Date of Publication: 07 November 2002

ISSN Information:

DOI: 10.1109/TED.2002.802624

Citations are not available for this document.

Contents

I. Introduction

For high-speed logic applications, suppression of the power consumption is very important and thus supply voltage should be reduced at every new generation. In order to realize high performance despite a low supply voltage, gate oxide thickness has to be reduced continuously. In fact, 2.0 nm–1.5 nm SiO₂ gate MOSFETs have already been demonstrated for high-end microprocessor products. Furthermore, it has been suggested that even 1.6–1.1 nm gate SiO₂ could be used for 45-nm gate length MOSFETs in 100-nm technology node [1].

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