An investigation of single-event effects and potential seu mitigation strategies in fourth-generation, 90 nm sige bicmos

Nelson E. Lourenco; Stanley D. Phillips; Troy D. England; Adilson S. Cardoso; Zachary E. Fleetwood; Kurt A. Moen; Dale McMorrow; Jeffrey H. Warner; Stephen P. Buchner; Pauline Paki-Amouzou; Jack Pekarik; David Harame; Ashok Raman; Marek Turowski; John D. Cressler

doi:10.1109/TNS.2013.2290301

An investigation of single-event effects and potential seu mitigation strategies in fourth-generation, 90 nm sige bicmos

Nelson E. Lourenco
, Stanley D. Phillips
, Troy D. England
, Adilson S. Cardoso
, Zachary E. Fleetwood
, Kurt A. Moen
, Dale McMorrow
, Jeffrey H. Warner
, Stephen P. Buchner
, Pauline Paki-Amouzou
, Jack Pekarik
, David Harame
, Ashok Raman
, Marek Turowski
, John D. Cressler

NY Creates Research Foundation

NY Creates

Georgia Institute of Technology
Texas Instruments
TOWER Semiconductor Ltd.
Naval Research Laboratory
Defense Threat Reduction Agency
Global Foundries, Inc.
CFD Research Corporation
Robust Chip Inc.

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

25 Scopus citations

Abstract

The single-event effect sensitivity of fourth-generation, 90 nm SiGe HBTs is investigated. Inverse-mode, $ \geq 1.0~\hbox{Gbps}$ SiGe digital logic using standard, unoptimized, fourth-generation SiGe HBTs is demonstrated and the inverse-mode shift register exhibited a reduction in bit-error cross section across all ion-strike LETs. Ion-strike simulations on dc calibrated, 3-D TCAD SiGe HBT models show a reduction in peak current transient magnitude and a reduction in overall transient duration for bulk SiGe HBTs operating in inverse mode. These improvements in device-level SETs are attributed to the electrical isolation of the physical emitter from the subcollector-substrate junction and the high doping in the SiGe HBT base and emitter, suggesting that SiGe BiCMOS technology scaling will drive further improvements in inverse-mode device and circuit-level SEE. Two-photon absorption experiments at NRL support the transient mechanisms described in the device-level TCAD simulations. Fully-coupled mixed-mode simulations predict large improvements in circuit-level SEU for inverse-mode SiGe HBTs in multi-Gbps, inverse-mode digital logic.

Original language	English
Article number	6678663
Pages (from-to)	4175-4183
Number of pages	9
Journal	IEEE Transactions on Nuclear Science
Volume	60
Issue number	6
DOIs	https://doi.org/10.1109/TNS.2013.2290301
State	Published - Dec 2013

Keywords

Inverse-mode operation
SEE
SET
SEU
SiGe HBT
TCAD
mixed-mode simulation
radiation hardening
single-event effects
single-event transient
single-event upset

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10.1109/TNS.2013.2290301

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Lourenco, N. E., Phillips, S. D., England, T. D., Cardoso, A. S., Fleetwood, Z. E., Moen, K. A., McMorrow, D., Warner, J. H., Buchner, S. P., Paki-Amouzou, P., Pekarik, J., Harame, D., Raman, A., Turowski, M., & Cressler, J. D. (2013). An investigation of single-event effects and potential seu mitigation strategies in fourth-generation, 90 nm sige bicmos. IEEE Transactions on Nuclear Science, 60(6), 4175-4183. Article 6678663. https://doi.org/10.1109/TNS.2013.2290301

@article{069e24a988ac4a118f7c6f4a341fccc3,

title = "An investigation of single-event effects and potential seu mitigation strategies in fourth-generation, 90 nm sige bicmos",

abstract = "The single-event effect sensitivity of fourth-generation, 90 nm SiGe HBTs is investigated. Inverse-mode, \$ \textbackslash{}geq 1.0\textasciitilde{}\textbackslash{}hbox\{Gbps\}\$ SiGe digital logic using standard, unoptimized, fourth-generation SiGe HBTs is demonstrated and the inverse-mode shift register exhibited a reduction in bit-error cross section across all ion-strike LETs. Ion-strike simulations on dc calibrated, 3-D TCAD SiGe HBT models show a reduction in peak current transient magnitude and a reduction in overall transient duration for bulk SiGe HBTs operating in inverse mode. These improvements in device-level SETs are attributed to the electrical isolation of the physical emitter from the subcollector-substrate junction and the high doping in the SiGe HBT base and emitter, suggesting that SiGe BiCMOS technology scaling will drive further improvements in inverse-mode device and circuit-level SEE. Two-photon absorption experiments at NRL support the transient mechanisms described in the device-level TCAD simulations. Fully-coupled mixed-mode simulations predict large improvements in circuit-level SEU for inverse-mode SiGe HBTs in multi-Gbps, inverse-mode digital logic.",

keywords = "Inverse-mode operation, SEE, SET, SEU, SiGe HBT, TCAD, mixed-mode simulation, radiation hardening, single-event effects, single-event transient, single-event upset",

author = "Lourenco, \{Nelson E.\} and Phillips, \{Stanley D.\} and England, \{Troy D.\} and Cardoso, \{Adilson S.\} and Fleetwood, \{Zachary E.\} and Moen, \{Kurt A.\} and Dale McMorrow and Warner, \{Jeffrey H.\} and Buchner, \{Stephen P.\} and Pauline Paki-Amouzou and Jack Pekarik and David Harame and Ashok Raman and Marek Turowski and Cressler, \{John D.\}",

year = "2013",

month = dec,

doi = "10.1109/TNS.2013.2290301",

language = "English",

volume = "60",

pages = "4175--4183",

journal = "IEEE Transactions on Nuclear Science",

issn = "0018-9499",

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

number = "6",

}

Lourenco, NE, Phillips, SD, England, TD, Cardoso, AS, Fleetwood, ZE, Moen, KA, McMorrow, D, Warner, JH, Buchner, SP, Paki-Amouzou, P, Pekarik, J, Harame, D, Raman, A, Turowski, M & Cressler, JD 2013, 'An investigation of single-event effects and potential seu mitigation strategies in fourth-generation, 90 nm sige bicmos', IEEE Transactions on Nuclear Science, vol. 60, no. 6, 6678663, pp. 4175-4183. https://doi.org/10.1109/TNS.2013.2290301

TY - JOUR

T1 - An investigation of single-event effects and potential seu mitigation strategies in fourth-generation, 90 nm sige bicmos

AU - Lourenco, Nelson E.

AU - Phillips, Stanley D.

AU - England, Troy D.

AU - Cardoso, Adilson S.

AU - Fleetwood, Zachary E.

AU - Moen, Kurt A.

AU - McMorrow, Dale

AU - Warner, Jeffrey H.

AU - Buchner, Stephen P.

AU - Paki-Amouzou, Pauline

AU - Pekarik, Jack

AU - Harame, David

AU - Raman, Ashok

AU - Turowski, Marek

AU - Cressler, John D.

PY - 2013/12

Y1 - 2013/12

N2 - The single-event effect sensitivity of fourth-generation, 90 nm SiGe HBTs is investigated. Inverse-mode, $ \geq 1.0~\hbox{Gbps}$ SiGe digital logic using standard, unoptimized, fourth-generation SiGe HBTs is demonstrated and the inverse-mode shift register exhibited a reduction in bit-error cross section across all ion-strike LETs. Ion-strike simulations on dc calibrated, 3-D TCAD SiGe HBT models show a reduction in peak current transient magnitude and a reduction in overall transient duration for bulk SiGe HBTs operating in inverse mode. These improvements in device-level SETs are attributed to the electrical isolation of the physical emitter from the subcollector-substrate junction and the high doping in the SiGe HBT base and emitter, suggesting that SiGe BiCMOS technology scaling will drive further improvements in inverse-mode device and circuit-level SEE. Two-photon absorption experiments at NRL support the transient mechanisms described in the device-level TCAD simulations. Fully-coupled mixed-mode simulations predict large improvements in circuit-level SEU for inverse-mode SiGe HBTs in multi-Gbps, inverse-mode digital logic.

AB - The single-event effect sensitivity of fourth-generation, 90 nm SiGe HBTs is investigated. Inverse-mode, $ \geq 1.0~\hbox{Gbps}$ SiGe digital logic using standard, unoptimized, fourth-generation SiGe HBTs is demonstrated and the inverse-mode shift register exhibited a reduction in bit-error cross section across all ion-strike LETs. Ion-strike simulations on dc calibrated, 3-D TCAD SiGe HBT models show a reduction in peak current transient magnitude and a reduction in overall transient duration for bulk SiGe HBTs operating in inverse mode. These improvements in device-level SETs are attributed to the electrical isolation of the physical emitter from the subcollector-substrate junction and the high doping in the SiGe HBT base and emitter, suggesting that SiGe BiCMOS technology scaling will drive further improvements in inverse-mode device and circuit-level SEE. Two-photon absorption experiments at NRL support the transient mechanisms described in the device-level TCAD simulations. Fully-coupled mixed-mode simulations predict large improvements in circuit-level SEU for inverse-mode SiGe HBTs in multi-Gbps, inverse-mode digital logic.

KW - Inverse-mode operation

KW - SEE

KW - SET

KW - SEU

KW - SiGe HBT

KW - TCAD

KW - mixed-mode simulation

KW - radiation hardening

KW - single-event effects

KW - single-event transient

KW - single-event upset

UR - https://www.scopus.com/pages/publications/84891531574

U2 - 10.1109/TNS.2013.2290301

DO - 10.1109/TNS.2013.2290301

M3 - Article

SN - 0018-9499

VL - 60

SP - 4175

EP - 4183

JO - IEEE Transactions on Nuclear Science

JF - IEEE Transactions on Nuclear Science

IS - 6

M1 - 6678663

ER -

An investigation of single-event effects and potential seu mitigation strategies in fourth-generation, 90 nm sige bicmos

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Keywords

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