Reducing Migration of Sintered Ag for Power Devices Operating at High Temperature

Dan Li; Yunhui Mei; Yunchang Xin; Zhiqiao Li; Paul K. Chu; Changsheng Ma; Guo-Quan Lu

doi:10.1109/TPEL.2020.2994343

Reducing Migration of Sintered Ag for Power Devices Operating at High Temperature

Dan Li, Yunhui Mei^*, Yunchang Xin^*, Zhiqiao Li, Paul K. Chu, Changsheng Ma, Guo-Quan Lu

^*Corresponding author for this work

Department of Materials Science and Engineering

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

32 Citations (Scopus)

Abstract

Wide-bandgap power devices are usually operated at a higher temperature or larger electrical bias and the harsh conditions often lead to early failure of the widely used Ag-based die-attach materials due to electrochemical migration (ECM). Common methods to mitigate ECM tend to be quite costly and can only enhance the performance slightly under high-temperature conditions. In this letter, novel nano-Ag-based die-attach materials are designed and prepared by doping with 0.1 wt% Si nanoparticles. The higher affinity of Si to oxygen reduces oxidation of silver and increases the median time to failure at 400 °C by 4.8 times. According to the life prediction model, the materials extend the lifetime for operation at 200 °C from 9.5 to 63 years, while the cost remains unchanged. The sintered nano-Ag-0.1%Si die attachment has long-term reliability rendering them desirable for power devices operating at a high temperature.

Original language	English
Pages (from-to)	12646-12650
Journal	IEEE Transactions on Power Electronics
Volume	35
Issue number	12
Online published	13 May 2020
DOIs	https://doi.org/10.1109/TPEL.2020.2994343
Publication status	Published - Dec 2020

Research Keywords

Electrochemical migration (ECM)
high temperatures
nano-AG
sintering

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title = "Reducing Migration of Sintered Ag for Power Devices Operating at High Temperature",

abstract = "Wide-bandgap power devices are usually operated at a higher temperature or larger electrical bias and the harsh conditions often lead to early failure of the widely used Ag-based die-attach materials due to electrochemical migration (ECM). Common methods to mitigate ECM tend to be quite costly and can only enhance the performance slightly under high-temperature conditions. In this letter, novel nano-Ag-based die-attach materials are designed and prepared by doping with 0.1 wt% Si nanoparticles. The higher affinity of Si to oxygen reduces oxidation of silver and increases the median time to failure at 400 °C by 4.8 times. According to the life prediction model, the materials extend the lifetime for operation at 200 °C from 9.5 to 63 years, while the cost remains unchanged. The sintered nano-Ag-0.1%Si die attachment has long-term reliability rendering them desirable for power devices operating at a high temperature.",

keywords = "Electrochemical migration (ECM), high temperatures, nano-AG, sintering, Electrochemical migration (ECM), high temperatures, nano-AG, sintering, Electrochemical migration (ECM), high temperatures, nano-AG, sintering",

author = "Dan Li and Yunhui Mei and Yunchang Xin and Zhiqiao Li and Chu, {Paul K.} and Changsheng Ma and Guo-Quan Lu",

year = "2020",

month = dec,

doi = "10.1109/TPEL.2020.2994343",

language = "English",

volume = "35",

pages = "12646--12650",

journal = "IEEE Transactions on Power Electronics",

issn = "0885-8993",

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T1 - Reducing Migration of Sintered Ag for Power Devices Operating at High Temperature

AU - Li, Dan

AU - Mei, Yunhui

AU - Xin, Yunchang

AU - Li, Zhiqiao

AU - Chu, Paul K.

AU - Ma, Changsheng

AU - Lu, Guo-Quan

PY - 2020/12

Y1 - 2020/12

N2 - Wide-bandgap power devices are usually operated at a higher temperature or larger electrical bias and the harsh conditions often lead to early failure of the widely used Ag-based die-attach materials due to electrochemical migration (ECM). Common methods to mitigate ECM tend to be quite costly and can only enhance the performance slightly under high-temperature conditions. In this letter, novel nano-Ag-based die-attach materials are designed and prepared by doping with 0.1 wt% Si nanoparticles. The higher affinity of Si to oxygen reduces oxidation of silver and increases the median time to failure at 400 °C by 4.8 times. According to the life prediction model, the materials extend the lifetime for operation at 200 °C from 9.5 to 63 years, while the cost remains unchanged. The sintered nano-Ag-0.1%Si die attachment has long-term reliability rendering them desirable for power devices operating at a high temperature.

AB - Wide-bandgap power devices are usually operated at a higher temperature or larger electrical bias and the harsh conditions often lead to early failure of the widely used Ag-based die-attach materials due to electrochemical migration (ECM). Common methods to mitigate ECM tend to be quite costly and can only enhance the performance slightly under high-temperature conditions. In this letter, novel nano-Ag-based die-attach materials are designed and prepared by doping with 0.1 wt% Si nanoparticles. The higher affinity of Si to oxygen reduces oxidation of silver and increases the median time to failure at 400 °C by 4.8 times. According to the life prediction model, the materials extend the lifetime for operation at 200 °C from 9.5 to 63 years, while the cost remains unchanged. The sintered nano-Ag-0.1%Si die attachment has long-term reliability rendering them desirable for power devices operating at a high temperature.

KW - Electrochemical migration (ECM)

KW - high temperatures

KW - nano-AG

KW - sintering

KW - Electrochemical migration (ECM)

KW - high temperatures

KW - nano-AG

KW - sintering

KW - Electrochemical migration (ECM)

KW - high temperatures

KW - nano-AG

KW - sintering

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U2 - 10.1109/TPEL.2020.2994343

DO - 10.1109/TPEL.2020.2994343

M3 - RGC 21 - Publication in refereed journal

SN - 0885-8993

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EP - 12650

JO - IEEE Transactions on Power Electronics

JF - IEEE Transactions on Power Electronics

IS - 12

ER -

Reducing Migration of Sintered Ag for Power Devices Operating at High Temperature

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Research Keywords

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Reducing Migration of Sintered Ag for Power Devices Operating at High Temperature

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ITF: Development of Key Technology to Attain a Novel Kind of Artificial Acetabulum

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