PBTI-associated high-temperature hot carrier degradation of nMOSFETs with metal-gate/high-κ dielectrics

Kyong Taek Lee; Chang Yong Kang; Ook Sang Yoo; Rino Choi; Byoung Hun Lee; Jack C. Lee; Hi Deok Lee; Yoon Ha Jeong

doi:10.1109/LED.2008.918257

PBTI-associated high-temperature hot carrier degradation of nMOSFETs with metal-gate/high-κ dielectrics

Kyong Taek Lee, Chang Yong Kang, Ook Sang Yoo, Rino Choi, Byoung Hun Lee, Jack C. Lee, Hi Deok Lee, Yoon Ha Jeong

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

49 Scopus citations

Abstract

Due to the increased physical dielectric thickness and reduced gate leakage in metal-gate/high-k devices, degradation caused by channel hot carriers (HCs) becomes more significant than positive bias temperature stress. In an analysis of metal-gate/high-k devices, accelerated channel HCs were found to induce permanent interface damage. Moreover, the overall threshold voltage shifts caused by HC stress were enhanced at higher temperatures, which is due to an association with positive bias temperature instability. Therefore, high-temperature HC stress has emerged as a dominant degradation factor in short-channel nMOSFETs with metal-gate/high-κ dielectrics.

Original language	English
Pages (from-to)	389-391
Number of pages	3
Journal	IEEE Electron Device Letters
Volume	29
Issue number	4
DOIs	https://doi.org/10.1109/LED.2008.918257
State	Published - Apr 2008

Keywords

Hot carrier (HC)
Metal-gate/high-κ dielectrics
Positive bias temperature instability (PBTI)

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10.1109/LED.2008.918257

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title = "PBTI-associated high-temperature hot carrier degradation of nMOSFETs with metal-gate/high-κ dielectrics",

abstract = "Due to the increased physical dielectric thickness and reduced gate leakage in metal-gate/high-k devices, degradation caused by channel hot carriers (HCs) becomes more significant than positive bias temperature stress. In an analysis of metal-gate/high-k devices, accelerated channel HCs were found to induce permanent interface damage. Moreover, the overall threshold voltage shifts caused by HC stress were enhanced at higher temperatures, which is due to an association with positive bias temperature instability. Therefore, high-temperature HC stress has emerged as a dominant degradation factor in short-channel nMOSFETs with metal-gate/high-κ dielectrics.",

keywords = "Hot carrier (HC), Metal-gate/high-κ dielectrics, Positive bias temperature instability (PBTI)",

author = "Lee, {Kyong Taek} and Kang, {Chang Yong} and Yoo, {Ook Sang} and Rino Choi and Lee, {Byoung Hun} and Lee, {Jack C.} and Lee, {Hi Deok} and Jeong, {Yoon Ha}",

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T1 - PBTI-associated high-temperature hot carrier degradation of nMOSFETs with metal-gate/high-κ dielectrics

AU - Lee, Kyong Taek

AU - Kang, Chang Yong

AU - Yoo, Ook Sang

AU - Choi, Rino

AU - Lee, Byoung Hun

AU - Lee, Jack C.

AU - Lee, Hi Deok

AU - Jeong, Yoon Ha

PY - 2008/4

Y1 - 2008/4

N2 - Due to the increased physical dielectric thickness and reduced gate leakage in metal-gate/high-k devices, degradation caused by channel hot carriers (HCs) becomes more significant than positive bias temperature stress. In an analysis of metal-gate/high-k devices, accelerated channel HCs were found to induce permanent interface damage. Moreover, the overall threshold voltage shifts caused by HC stress were enhanced at higher temperatures, which is due to an association with positive bias temperature instability. Therefore, high-temperature HC stress has emerged as a dominant degradation factor in short-channel nMOSFETs with metal-gate/high-κ dielectrics.

AB - Due to the increased physical dielectric thickness and reduced gate leakage in metal-gate/high-k devices, degradation caused by channel hot carriers (HCs) becomes more significant than positive bias temperature stress. In an analysis of metal-gate/high-k devices, accelerated channel HCs were found to induce permanent interface damage. Moreover, the overall threshold voltage shifts caused by HC stress were enhanced at higher temperatures, which is due to an association with positive bias temperature instability. Therefore, high-temperature HC stress has emerged as a dominant degradation factor in short-channel nMOSFETs with metal-gate/high-κ dielectrics.

KW - Hot carrier (HC)

KW - Metal-gate/high-κ dielectrics

KW - Positive bias temperature instability (PBTI)

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DO - 10.1109/LED.2008.918257

M3 - Article

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JO - IEEE Electron Device Letters

JF - IEEE Electron Device Letters

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ER -

PBTI-associated high-temperature hot carrier degradation of nMOSFETs with metal-gate/high-κ dielectrics

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