TY - GEN
T1 - Higher thermal cycling reliability of power semiconductor module for power converters
AU - Morozumi, Akira
AU - Hokazono, H.
AU - Nishimura, Yoshitaka
AU - Kariya, Yoshiharu
AU - Mochizuki, Eiji
AU - Takahashi, Yoshikazu
PY - 2016/6/7
Y1 - 2016/6/7
N2 - Power semiconductor devices for electric power conversion must be highly efficient, compact, and with large capacity. Therefore, highly thermo stability and long fatigue lifetime are necessary for the joint materials of these devices. In this paper, we discuss the joint reliability obtained by applying the supersaturated Sn-13wt. % Sb binary alloy. Through this process, the joint materials achieve a thermo stable up to 175 °C or more. Thus, they can be used in wide-bandgap semiconductors to join the ceramic substrate with the heat sink. Finally, we examine the new material properties (tensile and low cycling fatigue). The thermal cycling lifetime of supersaturated Sn-Sb joints is significantly affected by the material's microstructure; when its crystal grains are large, the material has a longer lifetime. Consequently, in SbSn compounds, which crystallize in the β-Sn matrix, solder crack propagation can be prevented when the compound is large enough; there is a mechanism that suppresses the propagation speed of the crack. In addition, the supersaturated Sn-13wt. %Sb binary alloy is also resistant up to 150 °C, above the higher temperature at which the joints are exposed to. Therefore, this application can ensure high reliability for the high temperature operating devices, which operate at 175 °C temperature or higher.
AB - Power semiconductor devices for electric power conversion must be highly efficient, compact, and with large capacity. Therefore, highly thermo stability and long fatigue lifetime are necessary for the joint materials of these devices. In this paper, we discuss the joint reliability obtained by applying the supersaturated Sn-13wt. % Sb binary alloy. Through this process, the joint materials achieve a thermo stable up to 175 °C or more. Thus, they can be used in wide-bandgap semiconductors to join the ceramic substrate with the heat sink. Finally, we examine the new material properties (tensile and low cycling fatigue). The thermal cycling lifetime of supersaturated Sn-Sb joints is significantly affected by the material's microstructure; when its crystal grains are large, the material has a longer lifetime. Consequently, in SbSn compounds, which crystallize in the β-Sn matrix, solder crack propagation can be prevented when the compound is large enough; there is a mechanism that suppresses the propagation speed of the crack. In addition, the supersaturated Sn-13wt. %Sb binary alloy is also resistant up to 150 °C, above the higher temperature at which the joints are exposed to. Therefore, this application can ensure high reliability for the high temperature operating devices, which operate at 175 °C temperature or higher.
KW - Crack propagation
KW - Sn-Sb binary alloy
KW - Solidification rate
KW - Strengthening mechanism
KW - Thermal cycling test
KW - Thermal stress
KW - Wide-bandgap semiconductor
UR - http://www.scopus.com/inward/record.url?scp=84978280574&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=84978280574&partnerID=8YFLogxK
U2 - 10.1109/ICEP.2016.7486857
DO - 10.1109/ICEP.2016.7486857
M3 - Conference contribution
AN - SCOPUS:84978280574
T3 - 2016 International Conference on Electronics Packaging, ICEP 2016
SP - 405
EP - 410
BT - 2016 International Conference on Electronics Packaging, ICEP 2016
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2016 International Conference on Electronics Packaging, ICEP 2016
Y2 - 20 April 2016 through 22 April 2016
ER -