Online from: 1989
Subject Area: Electrical & Electronic Engineering
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|Title:||Characterization of Sn7In4.1Ag0.5Cu solder in lead-free composite solder joints of LTCC/PWB assembly|
|Author(s):||O. Nousiainen, (Materials Engineering Laboratory and EMPART Research Group of Infotech Oulu, University of Oulu, Oulu, Finland), T. Kangasvieri, (Microelectronics and Materials Physics Laboratories and EMPART Research Group of Infotech Oulu, University of Oulu, Oulu, Finland), R. Rautioaho, (Materials Engineering Laboratory and EMPART Research Group of Infotech Oulu, University of Oulu, Oulu, Finland), J. Vähäkangas, (Microelectronics and Materials Physics Laboratories and EMPART Research Group of Infotech Oulu, University of Oulu, Oulu, Finland)|
|Citation:||O. Nousiainen, T. Kangasvieri, R. Rautioaho, J. Vähäkangas, (2008) "Characterization of Sn7In4.1Ag0.5Cu solder in lead-free composite solder joints of LTCC/PWB assembly", Soldering & Surface Mount Technology, Vol. 20 Iss: 3, pp.11 - 17|
|Keywords:||Alloys, Fatigue, Head, Solders, Thermal measurement|
|Article type:||Research paper|
|DOI:||10.1108/09540910810885679 (Permanent URL)|
|Publisher:||Emerald Group Publishing Limited|
|Acknowledgements:||The authors acknowledge the financial support of Tekes (the Finnish Funding Agency for Technology and Innovation) under the ACERMI project (40114/06) and the Graduate School of Infotech Oulu.|
Purpose – The purpose of this paper is to present a novel Sn7In4.1Ag0.5Cu/Plastic Core Solder Ball/Sn4Ag0.5Cu composite solder joint configuration for second-level ball grid array (BGA) interconnections of low temperature co-fired ceramic (LTCC) modules and the thermal fatigue durability of the configuration. The purpose of using the Sn7In4.1Ag0.5Cu solder was to increase the creep/fatigue resistance of critical regions on the LTCC side of the joint.
Design/methodology/approach – Test LTCC module/printed wiring board (PWB) assemblies were fabricated and exposed into temperature cycling tests over the 0 to 100°C and -40 to 125°C temperature ranges. The characteristic lifetimes of these assemblies were determined using DC resistance measurements. The failure mechanisms of the test assemblies were verified using scanning acoustic microscopy, FE-SEM, and SEM investigation.
Findings – The test assemblies were exposed to thermal cycling tests (TCT) over test ranges of 0 to 100°C and -40 to 125°C, and characteristic lifetimes of over 5,500 and 1,400 cycles, respectively, were achieved. Compared with Sn4Ag0.5Cu/plastic-core solder balls (PCSB)/Sn4Ag0.5Cu joints, the characteristic lifetime of the SAC-In/PCSB/SAC joints increased over 55 per cent in the harsh (-40 to 125°C) TCT conditions. In the milder test conditions (0 to 100°C), the characteristic lifetime of the SAC-In/PCSB/SAC joints increased 30 per cent compared with the SAC/PCSB/SAC joints.
Originality/value – The results proved that the enhanced creep/fatigue properties of the solder matrix resulted in satisfactory lifetime durations in the present lead-free composite solder joints and, consequently, different primary failure mechanisms on the LTCC side due to the use of indium alloyed solder. Thus, the present joint configuration is assumed to be a promising solution for the further design of a reliable second-level solder interconnection in LTCC/PWB assemblies with a high-global thermal mismatch.
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