Abstract
The present research work examines the microstructural arrangements formed during the transient solidification of eutectic Sn-0.2wt.%Ni and hypereutectic Sn-0.5wt.%Ni alloys. Also, it examines their respective correlations with solidification thermal parameters: eutectic growth rate (VE) and eutectic cooling rate (ṪE); length scales of matrix and eutectic phases: microstructural spacings and the corresponding tensile properties: ductility and strength. Both alloys were directionally solidified upwards under unsteady-state regime, and characterized by optical and scanning electron microscopy. Concerning the hypereutectic Sn-0.5wt.%Ni, the increase in Ni content is shown to influence both thermal behavior and cellular spacing (λC). The NiSn4 intermetallics is present in the eutectic mixture of both alloys, whilst in the Sn-0.5wt.%Ni alloy the primary phase has been identified by SEM-EDS as the Ni3Sn4 intermetallics. A β-Sn morphological cellular/dendritic transition occurs in the 0.2wt.%Ni eutectic alloy for ṪE> 1.2K/s. Despite that, regular cells in the hypereutectic alloy (0.5wt.%Ni) turns into plate-like cells for ṪE> 1.4K/s. If considered a reference cellular spacing about 20μm (i.e.,λ(c-1/2=0.22), the samples associated with the Sn-0.5wt.%Ni alloy are shown to be associated with higher tensile strengths, but much lower ductility as compared with the corresponding results of the eutectic alloy.
Highlights
Nickel (Ni) is one of the main alloying elements of Sn-based lead-free solder alloys
In order to gain insight into microstructure formation and solidification thermal parameters of eutectic Sn0.2wt.%Ni and hypereutectic Sn-0.5wt.%Ni solder alloys, the present study aims to examine the experimental growth dependence of microstructure features on the solidification cooling rate-Ṫ
Both eutectic and liquidus fronts were considered in the case of the hypereutectic Sn-0.5wt.%Ni alloy while only the eutectic front was followed for the eutectic Sn-0.2wt.%Ni alloy
Summary
Nickel (Ni) is one of the main alloying elements of Sn-based lead-free solder alloys. Determination of solidification conditions might yield either a specified β-Sn morphology and size or a required intermetallic particle in eutectic and hypereutectic Sn-Ni alloys Such lack of knowledge regarding Sn-Ni alloys is quite unexpected considering that Ni is a very common substrate in electronic packaging. The aim was to characterize microstructure features and determine their correlations with solidification thermal parameters, that is, the eutectic growth rate (VE) and the eutectic cooling rate (ṪE) This kind of knowledge ought to be expanded for Sn-Ni alloys. In order to gain insight into microstructure formation and solidification thermal parameters of eutectic Sn0.2wt.%Ni and hypereutectic Sn-0.5wt.%Ni solder alloys, the present study aims to examine the experimental growth dependence of microstructure features on the solidification cooling rate-Ṫ. Correlations between tensile strength, ductility and representative length scale of the microstructure are investigated
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