Donald W. Henderson

Effect of Sn grain orientation on electromigration degradation mechanism in high Sn-based Pb-free solders

Electromigration induced damage strongly depends on Sn-grain orientation in Pb-free solders. Rapid depletion of intermetallic compounds and under bump metallurgy led to significant damages caused by the fast diffusion of Cu and Ni along the c axis of Sn crystals. When the c axis of Sn grain is not aligned with the current direction, electromigration (EM) damage is dominated by Sn self-diffusion, which takes longer to occur. This is a direct proof of the highly anisotropic diffusion behavior in Sn. Due to the presence of twin structures and stable Ag3Sn network, SnAg(Cu) solders are less susceptible to grain orientation effects and showed better EM performance than SnCu solders.

Ag 3 Sn plate formation in the solidification of near ternary eutectic Sn–Ag–Cu alloys

Near-ternary eutectic Sn–Ag–Cu alloys are leading candidates for Pb-free solders. These alloys have three solid phases: β–Sn, Ag 3 Sn, and Cu 6 Sn 5 . Starting from the fully liquid state in solidifying near-eutectic Sn–Ag–Cu alloys, the equilibrium eutectic transformation is kinetically inhibited. The Ag 3 Sn phase nucleates with minimal undercooling, but the β–Sn phase requires a typical undercooling of 15 to 30 °C for nucleation. Because of this disparity in the required undercooling for nucleation, large, platelike Ag 3 Sn structures can grow rapidly within the liquid phase, before the final solidification of the solder joints. At lower cooling rates, the large Ag 3 Sn plates can subtend the entire cross section of solder joints and can significantly influence the mechanical deformation behavior of the solder joints under thermomechanical fatigue conditions. In this paper, it is demonstrated that the Ag 3 Sn plate formation can be inhibited, an important factor in assuring the reliability of solder joints composed of these alloys.

The microstructure of Sn in near-eutectic Sn–Ag–Cu alloy solder joints and its role in thermomechanical fatigue

During the solidification of solder joints composed of near-eutectic Sn-Ag-Cu alloys, the Sn phase grows rapidly with a dendritic growth morphology, characterized by copious branching. Notwithstanding the complicated Sn growth topology, the Sn phase demonstrates single crystallographic orientations over large regions. Typical solder ball grid array joints, 900 μm in diameter, are composed of 1 to perhaps 12 different Sn crystallographic domains (Sn grains). When such solder joints are submitted to cyclic thermomechanical strains, the solder joint fatigue process is characterized by the recrystallization of the Sn phase in the higher deformation regions with the production of a much smaller grain size. Grain boundary sliding and diffusion in these recrystallized regions then leads to extensive grain boundary damage and results in fatigue crack initiation and growth along the recrystallized Sn grain boundaries.

Simulation of structural anisotropy and void formation in amorphous thin films

We have computer simulated the structure of thin amorphous films grown from a vapor. Our hard‐sphere model shows that structural anisotropy and voids are a natural occurrence of the deposition process. The amount of unfilled space (voids) and the anisotropy have been studied as a function of the angle of incidence of the vapor stream upon the substrate.

Microstructure and mechanical properties of lead-free solders and solder joints used in microelectronic applications

The replacement of lead (Pb)-bearing solders used in the electronic industry with Pb-free solders will become a reality in the near future. Several promising Pb-free solders have recently been identified, including Sn-0.7Cu, Sn-3.5Ag, Sn-3.8Ag-0.7Cu, and Sn-3.5Ag-4.8Bi (in wt.% with slight variations in composition). These are all Sn-rich solders with melting temperatures between 210°C and 227°C, and are recommended for various soldering applications, including surface mount technology (SMT), plated-through-hole (PTH), ball grid array (BGA), flip-chip bumping, and others. Although a considerable amount of information on Pb-free solders has been published in the last few years, the database on these new materials is still at an infant stage compared with that for Pb-containing solders. This paper addresses several aspects of the current fundamental materials understanding associated with Pb-free solders and various issues regarding their imminent use in electronic interconnect applications, including microstructure-processing-property relations, mechanical properties, interfacial reactions, and the thermal-fatigue life and failure mechanisms of Pb-free solder joints.

Interfacial reactions of Sn-Ag-Cu solders modified by minor Zn alloying addition

The near-ternary eutectic Sn-Ag-Cu alloys have been identified as leading Pb-free solder candidates to replace Pb-bearing solders in microelectronic applications. However, recent investigations on the processing behavior and solder joints reliability assessment have revealed several potential reliability risk factors associated with the alloy system. The formation of large Ag3Sn plates in Sn-Ag-Cu joints, especially when solidified in a relatively slow cooling rate, is one issue of concern. The implications of large Ag3Sn plates on solder joint performance and several methods to control them have been discussed in previous studies. The minor Zn addition was found to be effective in reducing the amount of undercooling required for tin solidification and thereby to suppress the formation of large Ag3Sn plates. The Zn addition also caused the changes in the bulk microstructure as well as the interfacial reaction. In this paper, an in-depth characterization of the interfacial reaction of Zn-added Sn-Ag-Cu solders on Cu and Au/Ni(P) surface finishes is reported. The effects of a Zn addition on modification of the interfacial IMCs and their growth kinetics are also discussed.

Interfacial reaction studies on lead (Pb)-free solder alloys

Recently, the research and development activities for replacing Pb-containing solders with Pb-free solders have been intensified due to both competitive market pressures and environmental issues. As a result of these activities, a few promising candidate solder alloys have been identified, mainly, Sn-based alloys. A key issue affecting the integrity and reliability of solder joints is the interfacial reactions between a molten solder and surface finishes in the solder joint structures. In this paper, a fundamental study of the interfacial reactions between several Pb-free candidate solders and surface finishes commonly used in printed-circuit cards is reported. The Pb-free solders investigated include Sn-3.5 Ag, Sn-3.8 Ag-0.7 Cu, and Sn-3.5 Ag-3.0 Bi. The surface finishes investigated include Cu, Au/Ni(P), Au/Pd/Ni(P), and Au/Ni (electroplated). The reaction kinetics of the dissolution of surface finishes and intermetallic compound growth have been measured as a function of reflow temperature and time. The intermetallic compounds formed during reflow reactions have been identified by SEM with energy dispersive x-ray spectroscopy.

Evaluation of thermal fatigue life and failure mechanisms of Sn-Ag-Cu solder joints with reduced Ag contents

The electronic industry is making substantial progress toward a full transition to Pb-free soldering in the near future. At present, the leading candidate Pb-free solders are near-ternary eutectic Sn-Ag-Cu alloys. The electronic industry has begun to study both the processing behaviors and the thermomechanical fatigue properties of these alloys in detail in order to understand their applicability in context of current electronic card reliability requirements. In recent publications, the solidification behavior of the near-ternary eutectic Sn-Ag-Cu alloys has been reported in terms of the formation of large Ag/sub 3/Sn plates and their effects on mechanical properties of Pb-free solder joints. It was also demonstrated that reducing Ag content in the near-ternary eutectic Sn-Ag-Cu alloys was very effective in controlling the formation of large Ag/sub 3/Sn plates and thereby reducing the reliability risk factor of solder joints. In this study, thermal fatigue behavior of CBGA (ceramic ball grid array) solder joints was investigated in terms of Ag content, cooling rate, and thermal cycling conditions. Extensive failure analysis was conducted with thermal-cycled solder joints to understand the failure mechanisms operating during the accelerated thermal cycling (ATC) tests.

Comparison of electromigration performance for Pb-free solders and surface finishes with Ni UBM

A series of electromigration (EM) experiments were undertaken to evaluate the time to failure performance of solder joints comprised of Sn-Ag and Sn-Cu alloys in combination with three solderable surface finishes, Cu, Ni-Au and Ni-Cu. The opposing pad structure in the solder joints was the same in all experiments and was comprised of a layered structure, simulating Ni based under - bump - metallurgies (UBM) for controlled collapse chip connection (C4). As anticipated the Sn grain size was large with the typical solder joint containing only a few grains. In all experiments, reported here, the electron current exited the pad with the surface finish under evaluation and passed into the solder. Two failure modes were identified. The manifested failure mode depended on the orientation of the c-axis of the larger Sn grains in the solder joint with respect to the applied current direction. When the c-axis is not closely aligned with the current direction, cavitation at solder-IMC interface leads to electrical failure. A more rapid failure mode occurred when the c-axis was closely aligned with the current direction. With this alignment the interfacial IMC structures were swept away by rapid diffusive processes from the pad surface and the pad material was quickly consumed. Interfacial void formation leads to rapid failure in this mode. The Sn-Ag solder appeared to demonstrate greater microstructural stability. But, clearly the best EM performance was seen with the addition of significant levels of Cu to the Sn-Ag alloy. This alloy modification showed the best EM lifetime in combination with a Ni pad structure.

Interfacial reactions, microstructure and mechanical properties of Pb-free solder joints in PBGA laminates

Sn-based alloys have been developed as Pb-free solder candidates to replace the Pb-containing solders used in microelectronic applications. However, their high Sn content and high melting point often cause excessive interfacial reactions, namely, dissolution of surface finish layers and concomitant formation of intermetallic compounds at the soldering interface. These interfacial reactions can therefore influence the microstructure and mechanical properties of the solder joints and eventually their reliability. The choice of a proper surface finish layer in printed circuit boards is an important issue in successfully introducing the Sn-based, Pb-free solders. The effects of surface finish layers and multiple reflows on the BGA solder joints have been investigated. A Pb-free solder alloy, Sn-Ag-Cu has been employed as the solder ball material. Five types of surface finish on opposite sides of the BGA balls, have been investigated. Intermetallic compound formation was measured as a function of reflow cycle. The effects of the interfacial reactions on the microstructure and mechanical properties of the solder joints were also investigated as a function of surface finish and reflow cycle.