MICRO- AND NANO-PRECISION TESTING ON LOW TEMPERATURE SOLDERS

Colin Greene (10725279)

29 April 2021

Presently, a critical requirement in electronic assemblies is the reliability of solder joints. Accurate characterization of the mechanical behavior of solder alloys is challenging due to their micro-scale size, microstructural complexity, and complex rate-dependent mechanical behavior. This research presents two mechanical testers designed to acquire accurate mechanical response of the solder alloys. The testers allow using micro-scale test samples that replicate real solder joints in size and soldering pad metallurgy. <div>The first mechanical tester presented in this research is the micro-precision tester. It is capable of monotonic, creep and fatigue test profiles at testing temperatures between 25 and 75◦C. Using a closed-loop control scheme and an external capacitance sensor to minimize measurement of the load train compliance, the tester is capable of precision on the order of 0.1 µm. For load controlled tests, the tester is capable of precision on the order of 0.5 N. The design and construction processes are presented, including rationale for major design choices. Additionally, the development of custom squat-joint samples for use in this tester is presented. These samples allow for increased data reliability while maintaining realistic dimensions. Both validation and test data are presented to demonstrate the capabilities of the micro-precision tester. </div><div>A second mechanical tester, the nano-precision tester, was developed to address the need for increased accuracy as solder geometries shrink. Again, the design choices and limitations are presented, with emphasis on improvements over the micro-precision tester. The load and displacement control are approximately and order of magnitude better than that of the micro-precision tester. Example tests are presented to demonstrate the accuracy and capabilities of the nano-precision tester. </div><div>Finally, the thesis concludes with recommendations on methods to further improve the two testers. Specifically, for the micro-precision tester, thermal expansion during high-temperature testing is a significant concern. For the nano-precision tester, both validation of the tester the capability of multi-temperature testing are future work.<br></div>

Mechanical Engineering

LOW TEMPERATURE SOLDER

MECHANICAL BEHAVIOR

MECHANICAL TESTING

MICROALLOYING FOR STABLE LOW TEMPERATURE SOLDER MICROSTRUCTURE AND RELIABLE HETEROGENEOUS INTEGRATION: SB AND AG ADDITION TO LTS SN-BI

Hannah Nicole Fowler (16648578)

03 August 2023

<p> Low-temperature, lead-free solders mitigate heating-induced warpage caused by the  differences in coefficient of thermal expansion between printed circuit boards (PCBs), substrates,  and dies during package assembly. Eutectic and near-eutectic Sn-Bi solders are promising low  temperature candidates because they show high reliability at low strain rates during thermal  cycling. However, Sn-Bi low temperature solder (LTS) has poor performance at high strain rates  during drop-shock testing. Alloying additions such as Ag, Cu, and Sb have been shown to increase  the ductility and strength of eutectic Sn-Bi and therefore improve the overall reliability during both  thermal cycling and drop-shock. Small Sb additions to Sn-Bi LTS are of particular interest because  these additions significantly increase ductility while maintaining the tensile strength. This increase  in ductility was previously attributed to small SnSb intermetallic particles that form within the Sn  phase on the interface of Sn and Bi in 1.0wt% Sb containing samples. Despite the fact the no SnSb  intermetallic compound (IMC) particles have been found in 0.5Sb-42Sn-Bi samples in any  previous studies or in our own studies, it was thought that the SnSb IMC particles were responsible  for the improved reliability and ductility of Sn-Bi.  This work encloses our efforts to understand how small Sb additions to eutectic Sn-Bi  impact the solder microstructure and the resulting mechanical properties of the solder alloy. We  began by studying possible solidification pathways through phase diagram analysis in Thermo?Calc to understand how the microstructure is predicted to develop and compared these models to  the literature data. Next, we analyzed the microstructures of our custom Sb-containing alloys  through a combination of scanning electron microscopy (SEM), energy dispersive spectroscopy  (EDS), and electron probe microanalyzer-wavelength dispersive spectroscopy (EPMA-WDS) and  determined that no SnSb IMC particles were found in the 0.5Sb-42Sn-Bi alloy and at 0.5 wt% the  Sb remained in solid solution with Sn. Nanoindentation was then used to evaluate the strain rate  sensitivity of Sn-Bi LTS with Sb additions and we found that, while the alloy hardness remains  sensitive to different strain rates, the Sb in solid solution with Sn altered the deformation behavior  of the alloy and decreased the amount of planar slip during indentation. To study the stability of  the microstructure and the alloy behavior in use, shear testing was performed before and after  isothermal aging. Our results suggest that Sb in solid solution with the Sn-rich phase contributes  significantly to the changes in the eutectic microstructure and the mechanical properties. </p>

Metals and alloy materials

low temperature solder

Solder alloys