| description abstract | Most solders used in electronic systems have lowmelting temperature and hence experience significant amount of creep deformation throughout their lifecycle because typical operational and test conditions represent high homologous temperature. Phenomenological and mechanistic models used in the literature for predicting creep response of both bulk and grain scale specimens are reviewed in this paper. The phenomenological models reviewed in this paper are based on purely empirical observations of the creep deformation behavior or derived from qualitative interpretation of the underlying microscale mechanisms. These models have some intrinsic disadvantages since they do not have explicit mechanistic dependence on microstructural features. Therefore, the constitutive relations derived using the above models are difficult to extrapolate beyond the test conditions. This paper also reviews how some of the above limitations can be mitigated by using mechanistic or microstructurally motivated models. Mechanistic models are capable of estimating the material creep response based on the detailed physics of the underlying mechanisms and microstructure. The microstructure and constitutive response of the most popular family of leadfree solders, namely, SnAgCu (SAC) solders, are significantly different from those of previously used eutectic Sn37Pb solder. The creep deformation in Sn37Pb solder occurs primarily through diffusionassisted grainboundary sliding. In SAC solder joints, dislocationbased creep deformation mechanisms such as glide, climb, detachment, and crossslip appear to be the dominant mechanisms in coarsegrained joints. Mechanistic creep models are therefore based on the deformation mechanisms listed above. | |
