Activation Energy For Solder Bond Degradation: Thermal Cycling Of Field-Aged Modules At Multiple Upper Temperatures

The reliability of solder joints in the solar cell metallization-interconnect system influences the lifetime of photovoltaic modules. Two field-aged modules one with Sn62Pb36Ag2 solder at the solder joints (Solarex MSX 60), and the other with the standard Sn60Pb40 solder (Siemens M55)-were subjected to a modified thermal cycling (TC) test of IEC 61215. Three sections in each module were maintained at 85 degrees C, 95 degrees C, and 105 degrees C during the 15 -minute high temperature dwell time. Current equivalent to the module short-circuit current was injected through the module when the chamber temperature was above 25 degrees C to simulate regular field operation. This novel approach aims to induce thermomechanical fatigue (TMF) at the solder joints and intermetallic compound (IMC) formation at the metaUsolder interfaces. The activation energy (E-a) for solder bond degradation was calculated based on the series resistance (R-s) increase in TC testing rather than power drop to avoid the effect of confounding variables. Module-level Rs increase in MSX 60 module after TC800 cycles and in M55 module after TC400 cycles was 1.22% and 183.7% respectively. The E-a determined for the module with 2wt% Ag is 0.24 eV and for that with the standard solder is 0.27 eV. The solder bond degradation seems to have been driven by TMF rather than IMC formation for both modules.