Microstructure-based fatigue analysis of SiC power module with sintered silver die attach

Guo, Z. and Liang, S. and Ramachandran, S. and Jiang, H. and Xu, Y. and Zhong, Z. (2025) Microstructure-based fatigue analysis of SiC power module with sintered silver die attach. Power Electronic Devices and Components, 12. 100121. ISSN 2772-3704 (https://doi.org/10.1016/j.pedc.2025.100121)

Preview

Text. Filename: Guo-etal-PEDC-2025-Microstructure-based-fatigue-analysis-of-SiC-power-module.pdf Final Published Version License: Download (5MB)| Preview

Abstract

Sintered silver offers excellent performance for die-attach materials in power modules, but internal defects such as pores in sintered silver can decimate the mechanical behavior and overall lifetime of power modules. This work establishes a porous microstructure model of die-attached sintered silver by combining the Gaussian filter technique with macro finite element analysis. The model provides topology information for the assignment of material properties to sintered silver and enables the investigation of the porous microstructure effect. The thermo-mechanical behavior and fatigue lifetime of the power modules with different thicknesses of sintered silver die attach layers under power cycling are examined. Results show that the simulated porous microstructure of sintered silver is in good agreement with the experiment; the stress and viscoplastic dissipation energy density are higher for the power modules with thinner sintered silver die attach layer, and there is a significant stress concentration near the interface between the chip and sintered silver. Increasing sintered silver layer thickness reduces accumulated viscoplastic strain and improves the fatigue lifetime of the SiC power module, and the simulation results are consistent with the experimental observation. Furthermore, the pores significantly reduce the fatigue lifetimes of the power modules. The findings of this work would provide valuable insights for thermo-mechanical analysis and fatigue lifetime prediction of SiC power modules considering porous microstructures of sintered silver.

ORCID iDs

Ramachandran, S. ORCID: https://orcid.org/0000-0002-6881-2940

• Share and Export
  

  MPEG-21 DIDLJSONMETSRDF+N-TriplesOpenURL ContextObject in SpanAtomRefWorksMultiline CSVOpenURL ContextObjectDublin CoreRIOXX2 XMLReferEP3 XMLData Cite XMLMODSRDF+XMLHTML CitationASCII CitationRDF+N3EndNoteRIS (EndNote Online, Zotero, Ref manager, etc)Simple MetadataBibTeX
• Item metadata

  Item type:	Article
  ID code:	94424
  Dates:	Date Event 1 December 2025 Published 9 October 2025 Published Online 1 October 2025 Accepted
  Subjects:	Technology > Electrical engineering. Electronics Nuclear engineering Technology > Manufactures
  Department:	Faculty of Engineering > Design, Manufacture and Engineering Management > National Manufacturing Institute Scotland Faculty of Engineering > Design, Manufacture and Engineering Management > Advanced Forming Research Centre (AFRC)
  Depositing user:	Pure Administrator
  Date deposited:	13 Oct 2025 09:01
  Last modified:	03 Feb 2026 08:27
  URI:	https://strathprints.strath.ac.uk/id/eprint/94424