Optimization of Structurally Enhanced Solder Transient Liquid Phase Bonding

High temperature packaging technologies are a necessity for high temperature capable devices. SAC305 solder has an operational limit of 174℃ imposed by creep effects which aligns well with current junction temperature limits of 175℃. Wide band gap semiconductor materials have the potential to reach...

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Bibliographic Details
Published inInterSociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems pp. 1 - 5
Main Authors Harris, John, Huitink, David
Format Conference Proceeding
LanguageEnglish
Published IEEE 28.05.2024
Subjects
Costs
die attach
high temperature
Intermetallic
Microscopy
Nickel
Silver
Sintering
Substrates
Surface structures
Thermal stability
TLP
Transient analysis
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Summary:High temperature packaging technologies are a necessity for high temperature capable devices. SAC305 solder has an operational limit of 174℃ imposed by creep effects which aligns well with current junction temperature limits of 175℃. Wide band gap semiconductor materials have the potential to reach junction temperatures of up to 800℃ that are not currently attainable with significant reliability. Capitalizing on this potential will requires substrates and attachments that can operate well beyond the current 175℃ standard. Silver sintering pastes have received widespread interest as a high temperature attachment alternative. However, the process requires high pressure bonding in an inert environment to achieve acceptable bond quality. Transient liquid phase (TLP) sintering is capable of good bond quality without pressure requirements but suffers from low thermal conductivity and only slightly reduced cost compared to silver sintering. SAC305 solder contains the same constituent materials for TLP as available copper-tin TLP sintering paste. By introducing engineered surface structures into the bond, intermetallic formation can be accelerated producing a bond similar to TLP sintering but in an ambient environment and for reduced cost. While this process has been demonstrated, it has not yet been optimized. Currently bonds are formed using a 75 μm stencil on substrate surface structures 24 μm tall, covering 19% of the bonding area. The process takes about 4 hours not including the formation of surface structures. This study will center on the effects of stencil thickness and coating methods. Samples will be analyzed by scanning acoustic microscopy, die shear testing and cross sectional scanning acoustic microscopy.
ISSN:2694-2135
DOI:10.1109/ITherm55375.2024.10709536