Coarsening mechanisms, texture evolution and size distribution of Cu6Sn5 between Cu and Sn-based solders

During the reflowing procedure, the Cu concentration in the solder affects the coarsening mechanisms of intermetallic compound (IMC) grains. For the Sn3Cu solder, the mean radius of the IMC grains was proportional to the cube root of the reflowing time; while it follows the square root relation with...

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Bibliographic Details
Published in:Materials chemistry and physics 2011-12, Vol.131 (1-2), p.190-198
Main Authors: Zou, H.F., Yang, H.J., Zhang, Z.F.
Format: Article
Language:English
Subjects:
Coarsening
Copper
Grains
Roots
Size distribution
Solders
Texture
Tin
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Summary:During the reflowing procedure, the Cu concentration in the solder affects the coarsening mechanisms of intermetallic compound (IMC) grains. For the Sn3Cu solder, the mean radius of the IMC grains was proportional to the cube root of the reflowing time; while it follows the square root relation with the reflowing time for the SnAgCu and Sn solders. It is proposed that the flux from the substrate was only consumed to coarsen the IMC grains for Sn3Cu solder, while it was separated into two fluxes for the SnAgCu and Sn solders at the reflowing initial procedure. For the Sn3.8Ag0.7Cu/Cu and Sn/Cu couples, the size distribution of the IMC grains well agrees with the modified flux driven ripening (FDR) model when the value of r/aOE[copyraOEa is above 1; while it would closely match with Marqusee and Ross analysis when the value of r/aOE[copyraOEa is below 1. For Sn3Cu/Cu couple, the size distribution of IMC grains shows good agreement with the FDR model. However, for SnPb/poly-Cu, during the solid-state aging procedure, the mean radius of the IMC grains was proportional to the cube root of the aging time. And the size distribution of IMC grains is well consistent with the FDR model.
ISSN:0254-0584
DOI:10.1016/j.matchemphys.2011.08.061