Exploring the DC reliability metrics for scaled GaN-on-Si devices targeted for RF/5G applications

V. Putcha; E. Bury; J. Franco; A. Walke; S. E. Zhao; U. Peralagu; M. Zhao; A. Alian; B. Kaczer; N. Waldron; D. Linten; B. Parvais; N. Collaert

doi:10.1109/IRPS45951.2020.9129251

Exploring the DC reliability metrics for scaled GaN-on-Si devices targeted for RF/5G applications

V. Putcha
, E. Bury
, J. Franco
, A. Walke
, S. E. Zhao
, U. Peralagu
, M. Zhao
, A. Alian
, B. Kaczer
, N. Waldron
, D. Linten
, B. Parvais
, N. Collaert

Research output: Chapter in Book/Report/Conference proceedings › Chapter › peer-review

Abstract

GaN-channel based transistors are ideally suited for RF/5G applications and also provide the promise of monolithic integration on a conventional Si-platform. Due to the wide scope of high electron mobility GaN transistor architectures, their reliability assessment is essential to ensure their successful deployment in low-power applications such as mobile computing devices, as well as high-power applications such as autonomous vehicles and base stations. We identify the most important DCreliability metrics necessary for fair benchmarking of future GaNon-Si RF transistors. A detailed analysis of the shortlisted DCreliability parameters for three device types, namely MOSFETs, MOSHEMTs/MISHEMTs and HEMTs is presented. MOSHEMT/MISHEMT is identified as the most robust device architecture, due to the presence of a barrier layer alleviating the impact of certain degradation mechanisms. Defect distributions in the gate-stack of MOS devices are extracted using defect band modelling technique. MOSHEMT devices are shown to undergo negative and positive Bias Temperature Instability (BTI) under specific ranges of positive gate-overdrive, thereby demonstrating the importance of correctly estimating the oxide field for MOSHEMT devices. Degradation map methodology is partially developed to distinguish the different gate-oxide degradation mechanisms and model the device lifetime pertaining to each of the mechanisms.

Original language	English
Title of host publication	2020 IEEE International Reliability Physics Symposium, IRPS 2020 - Proceedings
Publisher	Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	9781728131993
DOIs	https://doi.org/10.1109/IRPS45951.2020.9129251
Publication status	Published - Apr 2020
Externally published	Yes
Event	2020 IEEE International Reliability Physics Symposium, IRPS 2020 - Virtual, Online, United States Duration: 28 Apr 2020 → 30 May 2020

Publication series

Name	IEEE International Reliability Physics Symposium Proceedings
Volume	2020-April
ISSN (Print)	1541-7026

Conference

Conference	2020 IEEE International Reliability Physics Symposium, IRPS 2020
Country/Territory	United States
City	Virtual, Online
Period	28/04/20 → 30/05/20

Keywords

buffer breakdown
buffer dispersion
DC-reliability
device breakdown
device lifetime.
GaN
RF/5G applications

Access to Document

10.1109/IRPS45951.2020.9129251

Cite this

Putcha, V., Bury, E., Franco, J., Walke, A., Zhao, S. E., Peralagu, U., Zhao, M., Alian, A., Kaczer, B., Waldron, N., Linten, D., Parvais, B., & Collaert, N. (2020). Exploring the DC reliability metrics for scaled GaN-on-Si devices targeted for RF/5G applications. In 2020 IEEE International Reliability Physics Symposium, IRPS 2020 - Proceedings Article 9129251 (IEEE International Reliability Physics Symposium Proceedings; Vol. 2020-April). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/IRPS45951.2020.9129251

@inbook{ba35b3bac6204dfcb783c9b886638d49,

title = "Exploring the DC reliability metrics for scaled GaN-on-Si devices targeted for RF/5G applications",

abstract = "GaN-channel based transistors are ideally suited for RF/5G applications and also provide the promise of monolithic integration on a conventional Si-platform. Due to the wide scope of high electron mobility GaN transistor architectures, their reliability assessment is essential to ensure their successful deployment in low-power applications such as mobile computing devices, as well as high-power applications such as autonomous vehicles and base stations. We identify the most important DCreliability metrics necessary for fair benchmarking of future GaNon-Si RF transistors. A detailed analysis of the shortlisted DCreliability parameters for three device types, namely MOSFETs, MOSHEMTs/MISHEMTs and HEMTs is presented. MOSHEMT/MISHEMT is identified as the most robust device architecture, due to the presence of a barrier layer alleviating the impact of certain degradation mechanisms. Defect distributions in the gate-stack of MOS devices are extracted using defect band modelling technique. MOSHEMT devices are shown to undergo negative and positive Bias Temperature Instability (BTI) under specific ranges of positive gate-overdrive, thereby demonstrating the importance of correctly estimating the oxide field for MOSHEMT devices. Degradation map methodology is partially developed to distinguish the different gate-oxide degradation mechanisms and model the device lifetime pertaining to each of the mechanisms.",

keywords = "buffer breakdown, buffer dispersion, DC-reliability, device breakdown, device lifetime., GaN, RF/5G applications",

author = "V. Putcha and E. Bury and J. Franco and A. Walke and Zhao, \{S. E.\} and U. Peralagu and M. Zhao and A. Alian and B. Kaczer and N. Waldron and D. Linten and B. Parvais and N. Collaert",

note = "Publisher Copyright: {\textcopyright} 2020 IEEE.; 2020 IEEE International Reliability Physics Symposium, IRPS 2020 ; Conference date: 28-04-2020 Through 30-05-2020",

year = "2020",

month = apr,

doi = "10.1109/IRPS45951.2020.9129251",

language = "English",

series = "IEEE International Reliability Physics Symposium Proceedings",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

booktitle = "2020 IEEE International Reliability Physics Symposium, IRPS 2020 - Proceedings",

address = "United States",

}

Putcha, V, Bury, E, Franco, J, Walke, A, Zhao, SE, Peralagu, U, Zhao, M, Alian, A, Kaczer, B, Waldron, N, Linten, D, Parvais, B & Collaert, N 2020, Exploring the DC reliability metrics for scaled GaN-on-Si devices targeted for RF/5G applications. in 2020 IEEE International Reliability Physics Symposium, IRPS 2020 - Proceedings., 9129251, IEEE International Reliability Physics Symposium Proceedings, vol. 2020-April, Institute of Electrical and Electronics Engineers Inc., 2020 IEEE International Reliability Physics Symposium, IRPS 2020, Virtual, Online, United States, 28/04/20. https://doi.org/10.1109/IRPS45951.2020.9129251

Exploring the DC reliability metrics for scaled GaN-on-Si devices targeted for RF/5G applications. / Putcha, V.; Bury, E.; Franco, J. et al.
2020 IEEE International Reliability Physics Symposium, IRPS 2020 - Proceedings. Institute of Electrical and Electronics Engineers Inc., 2020. 9129251 (IEEE International Reliability Physics Symposium Proceedings; Vol. 2020-April).

Research output: Chapter in Book/Report/Conference proceedings › Chapter › peer-review

TY - CHAP

T1 - Exploring the DC reliability metrics for scaled GaN-on-Si devices targeted for RF/5G applications

AU - Putcha, V.

AU - Bury, E.

AU - Franco, J.

AU - Walke, A.

AU - Zhao, S. E.

AU - Peralagu, U.

AU - Zhao, M.

AU - Alian, A.

AU - Kaczer, B.

AU - Waldron, N.

AU - Linten, D.

AU - Parvais, B.

AU - Collaert, N.

PY - 2020/4

Y1 - 2020/4

N2 - GaN-channel based transistors are ideally suited for RF/5G applications and also provide the promise of monolithic integration on a conventional Si-platform. Due to the wide scope of high electron mobility GaN transistor architectures, their reliability assessment is essential to ensure their successful deployment in low-power applications such as mobile computing devices, as well as high-power applications such as autonomous vehicles and base stations. We identify the most important DCreliability metrics necessary for fair benchmarking of future GaNon-Si RF transistors. A detailed analysis of the shortlisted DCreliability parameters for three device types, namely MOSFETs, MOSHEMTs/MISHEMTs and HEMTs is presented. MOSHEMT/MISHEMT is identified as the most robust device architecture, due to the presence of a barrier layer alleviating the impact of certain degradation mechanisms. Defect distributions in the gate-stack of MOS devices are extracted using defect band modelling technique. MOSHEMT devices are shown to undergo negative and positive Bias Temperature Instability (BTI) under specific ranges of positive gate-overdrive, thereby demonstrating the importance of correctly estimating the oxide field for MOSHEMT devices. Degradation map methodology is partially developed to distinguish the different gate-oxide degradation mechanisms and model the device lifetime pertaining to each of the mechanisms.

AB - GaN-channel based transistors are ideally suited for RF/5G applications and also provide the promise of monolithic integration on a conventional Si-platform. Due to the wide scope of high electron mobility GaN transistor architectures, their reliability assessment is essential to ensure their successful deployment in low-power applications such as mobile computing devices, as well as high-power applications such as autonomous vehicles and base stations. We identify the most important DCreliability metrics necessary for fair benchmarking of future GaNon-Si RF transistors. A detailed analysis of the shortlisted DCreliability parameters for three device types, namely MOSFETs, MOSHEMTs/MISHEMTs and HEMTs is presented. MOSHEMT/MISHEMT is identified as the most robust device architecture, due to the presence of a barrier layer alleviating the impact of certain degradation mechanisms. Defect distributions in the gate-stack of MOS devices are extracted using defect band modelling technique. MOSHEMT devices are shown to undergo negative and positive Bias Temperature Instability (BTI) under specific ranges of positive gate-overdrive, thereby demonstrating the importance of correctly estimating the oxide field for MOSHEMT devices. Degradation map methodology is partially developed to distinguish the different gate-oxide degradation mechanisms and model the device lifetime pertaining to each of the mechanisms.

KW - buffer breakdown

KW - buffer dispersion

KW - DC-reliability

KW - device breakdown

KW - device lifetime.

KW - GaN

KW - RF/5G applications

UR - https://www.scopus.com/pages/publications/85088361218

U2 - 10.1109/IRPS45951.2020.9129251

DO - 10.1109/IRPS45951.2020.9129251

M3 - Chapter

AN - SCOPUS:85088361218

T3 - IEEE International Reliability Physics Symposium Proceedings

BT - 2020 IEEE International Reliability Physics Symposium, IRPS 2020 - Proceedings

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 2020 IEEE International Reliability Physics Symposium, IRPS 2020

Y2 - 28 April 2020 through 30 May 2020

ER -

Putcha V, Bury E, Franco J, Walke A, Zhao SE, Peralagu U et al. Exploring the DC reliability metrics for scaled GaN-on-Si devices targeted for RF/5G applications. In 2020 IEEE International Reliability Physics Symposium, IRPS 2020 - Proceedings. Institute of Electrical and Electronics Engineers Inc. 2020. 9129251. (IEEE International Reliability Physics Symposium Proceedings). doi: 10.1109/IRPS45951.2020.9129251

Exploring the DC reliability metrics for scaled GaN-on-Si devices targeted for RF/5G applications

Abstract

Publication series

Conference

Keywords

Access to Document

Other files and links

Fingerprint

Cite this