Mechanism of electromigration-induced failure in the 97Pb–3Sn and 37Pb–63Sn composite solder joints

Nah, Jae-Woong; Paik, Kyung‐Wook; Suh, Jong-ook; Tu, K. N.

doi:10.1063/1.1628388

Cited by 141 publications

(67 citation statements)

References 11 publications

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“…2 However, the interface between the scallops and Cu has been investigated, except that it was assumed that the interfacial diffusion of Cu is fast and the diffusion is not a rate limiting step. In spite of the very large body of literature published on the subject of solder/Cu reaction, [3][4][5][6][7][8][9][10][11][12] the structural informa-tion of the interface and the crystallographic orientation reaPresent address: Jet Propulsion Laboratory, Pasadena, California; electronic mail: Jong-ook.Suh@jpl.nasa.gov lationship between the IMC and Cu is still missing. It is the purpose of this study to determine the orientation relationship and the statistical distribution experimentally.…”

Section: Introductionmentioning

confidence: 99%

Preferred orientation relationship between Cu6Sn5 scallop-type grains and Cu substrate in reactions between molten Sn-based solders and Cu

Suh

Tamura

2007

Journal of Applied Physics

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A strong crystallographic orientation relationship between the Cu6Sn5 scallop-type grains and their Cu substrate has been found by synchrotron micro-x-ray diffraction study. Even though the crystal structures of Cu6Sn5 (monoclinic) and Cu (face-centered-cubic) are very different, angular distributions of crystallographic directions between Cu6Sn5 and Cu revealed a strong orientation relationship. Both SnPb solder and pure Sn showed the same result, indicating that this is general behavior between Sn-based solders and Cu. The strong orientation relation suggests that Cu6Sn5 forms prior to Cu3Sn in the wetting reactions. A total of six different orientation relationships were found. In all the cases, the [1¯01] direction of Cu6Sn5 preferred to be parallel to the [110] direction of Cu with a misfit of 0.24%. Due to pseudohexagonal structure of the Cu6Sn5, the six relationships can be categorized into two groups. From the orientation distribution, one group was found to be less rigid then the other group.

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Section: Introductionmentioning

confidence: 99%

Preferred orientation relationship between Cu6Sn5 scallop-type grains and Cu substrate in reactions between molten Sn-based solders and Cu

Suh

Tamura

2007

Journal of Applied Physics

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“…Therefore, in-situ observation of the microstructural variation during the current stressing of the solder joints should be conducted to evaluate the effects of the two factors. The primary cause for current crowding is reported 15,16) to be the line-to-bump geometry of the solder bump joint, resulting in a higher current density in the solder regime than the average current density. However, the primary contributor for Joule heating in the solder joints is reported 15,16) to be the extremely thin and small dimension of Cu or Al traces on the Si chip.…”

Section: )mentioning

confidence: 99%

Electromigration Behavior of through-Si-via (TSV) Interconnect for 3-D Flip Chip Packaging

Yang

Jung

2010

Mater. Trans.

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“…5) Previous reports have indicated that the evolution of microstructural features and mechanical properties of solder alloys were significantly related to the EM effect by applying the DC power. [6][7][8] In general, solders stressed with current density above 10 8 AÁm À2 for several hours will trigger the EM effect, 9,10) and so will solders with a lower level of current density. 5,11,12) However, the EM effect can be ignored in the case of alternating current (AC) power.…”

Section: Introductionmentioning

confidence: 99%

Effect of Zinc Content on Microstructural Evolution and Electrification-Fusion-Induced Failure Mechanism of Sn-<I>x</I>Zn Alloys

et al. 2011

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Microstructural features of Sn-xZn alloys with varying Zn content of 7, 9, 20, 30 mass% on the electrification-fusion phenomenon were investigated in this study. Experimental results showed that the critical fusion current density (CFCD) of Sn-xZn alloys increased with increasing Zn content. The enrichment of Zn-rich phase was the main factor in the improvement of electrical conductivity and the required electrical current density for triggering microstructural evolution for the hypereutectic Sn-30Zn alloy was much higher than the hypoeutectic Sn-7Zn alloy. There is an obvious difference in the increase rate of CFCD from the hypoeutectic composition (Sn-7Zn) to the eutectic composition (Sn-9Zn) due to the microstructural evolution with increasing Zn content. Through the in-situ examination of microstructural evolution during electrificationfusion tests, the initial site of electrification-fusion-induced failure was significantly emerged from the Sn/Zn eutectic phase for both the hypoeutectic composition (Sn-7Zn) and the hypereutectic composition (Sn-30Zn). The fusion behavior of Sn-7Zn was dominated by double massive fusion regions on Sn/Zn eutectic phase and -Sn phase, whereas the fusion behavior of Sn-30Zn was dominated by massive fusion regions only on Sn/Zn eutectic phase.

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Mechanism of electromigration-induced failure in the 97Pb–3Sn and 37Pb–63Sn composite solder joints

Cited by 141 publications

References 11 publications

Preferred orientation relationship between Cu6Sn5 scallop-type grains and Cu substrate in reactions between molten Sn-based solders and Cu

Preferred orientation relationship between Cu6Sn5 scallop-type grains and Cu substrate in reactions between molten Sn-based solders and Cu

Electromigration Behavior of through-Si-via (TSV) Interconnect for 3-D Flip Chip Packaging

Effect of Zinc Content on Microstructural Evolution and Electrification-Fusion-Induced Failure Mechanism of Sn-<I>x</I>Zn Alloys

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