Hot-carrier degradation characteristics and explanation in 0.25 μm PMOSFETs

Hong Xia Liu; Yue Hao; I. D. Hawkins; A. R. Peaker

doi:10.1088/1009-1963/14/8/032

Hot-carrier degradation characteristics and explanation in 0.25 μm PMOSFETs

Hong Xia Liu^*, Yue Hao, I. D. Hawkins, A. R. Peaker

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

The hot-carrier effect (HCE) of deep-submicron PMOSFETs has been investigated. It is found that the HCE includes both generation of interface states and formation of positive fixed charges in the gate oxide. We present experimental evidences showing that two degradation mechanisms are important in the case of deep-submicron PMOSFETs. Firstly, the generation of positive fixed oxide charges is significant in the case of deep-submicron PMOSFETs, which degrades the threshold voltage and even limits the transistor lifetime. For advanced analogy and mixed signal applications, process and device reliability limits need to be set up based also on threshold voltage shift, in addition to traditional methods of the transconductance degradation or gate oxide lifetime. Secondly, the generation of interface states by holes influences the device characteristics. Some speculation on the HCE formation process is included.

Original language	English
Pages (from-to)	1644-1648
Number of pages	5
Journal	Chinese Physics
Volume	14
Issue number	8
DOIs	https://doi.org/10.1088/1009-1963/14/8/032
Publication status	Published - 1 Aug 2005

Keywords

Device reliability
Hot-carrier effect (HCE)
Interface states
PMOSFET
Positive fixed oxide charges

Research Beacons, Institutes and Platforms

Photon Science Institute

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10.1088/1009-1963/14/8/032

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title = "Hot-carrier degradation characteristics and explanation in 0.25 μm PMOSFETs",

abstract = "The hot-carrier effect (HCE) of deep-submicron PMOSFETs has been investigated. It is found that the HCE includes both generation of interface states and formation of positive fixed charges in the gate oxide. We present experimental evidences showing that two degradation mechanisms are important in the case of deep-submicron PMOSFETs. Firstly, the generation of positive fixed oxide charges is significant in the case of deep-submicron PMOSFETs, which degrades the threshold voltage and even limits the transistor lifetime. For advanced analogy and mixed signal applications, process and device reliability limits need to be set up based also on threshold voltage shift, in addition to traditional methods of the transconductance degradation or gate oxide lifetime. Secondly, the generation of interface states by holes influences the device characteristics. Some speculation on the HCE formation process is included.",

keywords = "Device reliability, Hot-carrier effect (HCE), Interface states, PMOSFET, Positive fixed oxide charges",

author = "Liu, {Hong Xia} and Yue Hao and Hawkins, {I. D.} and Peaker, {A. R.}",

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doi = "10.1088/1009-1963/14/8/032",

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T1 - Hot-carrier degradation characteristics and explanation in 0.25 μm PMOSFETs

AU - Liu, Hong Xia

AU - Hao, Yue

AU - Hawkins, I. D.

AU - Peaker, A. R.

PY - 2005/8/1

Y1 - 2005/8/1

N2 - The hot-carrier effect (HCE) of deep-submicron PMOSFETs has been investigated. It is found that the HCE includes both generation of interface states and formation of positive fixed charges in the gate oxide. We present experimental evidences showing that two degradation mechanisms are important in the case of deep-submicron PMOSFETs. Firstly, the generation of positive fixed oxide charges is significant in the case of deep-submicron PMOSFETs, which degrades the threshold voltage and even limits the transistor lifetime. For advanced analogy and mixed signal applications, process and device reliability limits need to be set up based also on threshold voltage shift, in addition to traditional methods of the transconductance degradation or gate oxide lifetime. Secondly, the generation of interface states by holes influences the device characteristics. Some speculation on the HCE formation process is included.

AB - The hot-carrier effect (HCE) of deep-submicron PMOSFETs has been investigated. It is found that the HCE includes both generation of interface states and formation of positive fixed charges in the gate oxide. We present experimental evidences showing that two degradation mechanisms are important in the case of deep-submicron PMOSFETs. Firstly, the generation of positive fixed oxide charges is significant in the case of deep-submicron PMOSFETs, which degrades the threshold voltage and even limits the transistor lifetime. For advanced analogy and mixed signal applications, process and device reliability limits need to be set up based also on threshold voltage shift, in addition to traditional methods of the transconductance degradation or gate oxide lifetime. Secondly, the generation of interface states by holes influences the device characteristics. Some speculation on the HCE formation process is included.

KW - Device reliability

KW - Hot-carrier effect (HCE)

KW - Interface states

KW - PMOSFET

KW - Positive fixed oxide charges

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Hot-carrier degradation characteristics and explanation in 0.25 μm PMOSFETs

Abstract

Keywords

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