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Abstract

The compressive creep behavior of eutectic tin-lead (Sn-Pb) alloy was studied through constant-load creep experiments on bulk specimens. These specimens were exposed to constant compressive stresses ranging from 10% to 100% of their yield strength, at temperatures escalating from room temperature (RT) to 140°C. Constitutive analysis of the primary creep rate revealed the inadequacy of a single power-law stress function. In the high-stress regime across these temperatures, a hyperbolic sine function effectively correlated the transient creep rate with the applied stress. Conversely, in the low-stress regime, a linear function aptly approximated the stress dependence of the transient creep rate. Modifications were made to the classical Norton-Bailey time/strain hardening model to accurately represent the unique primary creep characteristics of this alloy. Given the distinct stress functions of the transient creep rate, dislocation creep and diffusion creep were identified as the predominant creep mechanisms in the high and low-stress regimes, respectively. This comprehensive experimental investigation and constitutive analysis facilitated the construction of a transient creep deformation map, illuminating the underlying creep mechanisms of eutectic Sn-Pb alloy under varying stresses at elevated temperatures.

Keywords

Solder alloy compressive creep creep damage creep law low temperature alloy

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References

Abtew

Selvaduray

Lead-free solders in microelectronics. Mater Sci Eng R Rep 2000; 27: 95–141.

Handwerker

Kattner

Moon

KW.

Fundamental properties of Pb-free solder alloys. In: Lead-Free Soldering. Springer, 2007; 21–74.

Kotadia

Howes

Mannan

SH.

A review: on the development of low melting temperature Pb-free solders. Microelectron Reliab 2014; 54: 1253–1273.

Yang

, et al. Low temperature bonding for high temperature applications by using SnBi solders. J Alloys Comp 2015; 647: 681–685.

Hua

Mei

Glazer

Eutectic Sn-Bi as an alternative to Pb-free solders. In: 1998 Proceedings 48th electronic components and technology conference (Cat No 98CH36206), 1998, pp.277–283: IEEE.

Mei

Morris

JW.

Characterization of eutectic Sn-Bi solder joints. J Electron Mater 1992; 21: 599–607.

Morris

Goldstein

JLF

Mei

Microstructure and mechanical properties of Sn-In and Sn-Bi solders. JOM 1993; 45: 25–27.

Goldstein

JLF

Morris

. Microstructural development of eutectic Bi-Sn and eutectic In-Sn during high temperature deformation. J Electron Mater 1994; 23: 477–486.

Raeder

Mitlin

Messler

RW.

Modelling the creep rates of eutectic Bi–Sn solder using the data from its constitutive phases. J Mater Sci 1998; 33: 4503–4508.

10.

Mitlin

Raeder

Messler

RW.

Solid solution creep behavior of Sn-xBi alloys. Metallurgical Mater Trans A 1999; 30: 115–122.

11.

Reinikainen

Kivilahti

. Deformation behavior of dilute SnBi(0.5 to 6 at. Pct ) solid solutions. Metallurgical Mater Trans A 1999; 30: 123–132.

12.

Chen

Zhou

Xue

, et al. Mechanical deformation behavior and mechanism of Sn-58Bi solder alloys under different temperatures and strain rates. Mater Sci Eng A 2016; 662: 251–257.

13.

Zhang

Song

, et al. Viscoplastic creep and microstructure evolution of Sn-based lead-free solders at low strain. Mater Sci Eng A 2017; 701: 187–195.

14.

Alkorta

Sevillano

JG.

Measuring the strain rate sensitivity by instrumented indentation. Application to an ultrafine grain (equal channel angular–pressed) eutectic Sn–Bi alloy. J Mater Res 2004; 19: 282–290.

15.

Mahmudi

Geranmayeh

Mahmoodi

, et al. Room-temperature indentation creep of lead-free Sn–Bi solder alloys. J Mater Sci Mater Electron 2007; 18: 1071–1078.

16.

Mahmudi

Geranmayeh

Mahmoodi

, et al. Effect of cooling rate on the room-temperature indentation creep of cast lead-free Sn–Bi solder alloys. Phys Status Solidi B 2007; 204: 2302–2308.

17.

Liu

Chen

Nanoindentation of lead-free solders in microelectronic packaging. Mater Sci Eng A 2007; 448: 340–344.

18.

Shen

Septiwerdani

Chen

Elastic modulus, hardness and creep performance of SnBi alloys using nanoindentation. Mater Sci Eng A 2012; 558: 253–258.

19.

Shalaby

RM.

Effect of silver and indium addition on mechanical properties and indentation creep behavior of rapidly solidified Bi–Sn based lead-free solder alloys. Mater Sci Eng A 2013; 560: 86–95.

20.

Shen

Wang

, et al. Creep behaviour of eutectic SnBi alloy and its constituent phases using nanoindentation technique. J Alloys Comp 2013; 574: 98–103.

21.

Shen

Wang

, et al. Creep behavior of Sn–Bi solder alloys at elevated temperatures studied by nanoindentation. J Mater Sci Mater Electron 2017; 28: 4114–4124.

22.

Dudek

Döring

Michel

. Reliability prediction of area array solder joints. J Electron Packag 2003; 125(4): 562–568.

23.

Mukherjee

Zhou

Dasgupta

, et al. Multiscale modeling of the anisotropic transient creep response of heterogeneous single crystal SnAgCu solder. Int J Plast 2016; 78: 1–25.

24.

Kariya

Mechanical reliability of solders in small volume. J Jpn Inst Electron Packag 2006; 9: 138–142.

25.

Atkins

. Deformation-mechanism maps (the plasticity and creep of metals and ceramics): by H.J. Frost and M.F. Ashby, Pergamon, Oxford 1982. J Mech Work Technol 1984; 9(2): 224–225. DOI:10.1016/0378-3804(84)90015-9.

26.

Fensham

PJ.

Self-diffusion in tin crystals. Aus J Chem 1950; 3(1): 91.

27.

Kassner

. Fundamentals of creep in metals and alloys. J Fundam Creep Met & Alloys 2014; 7(7–8): 301–332.

28.

Nix

Gao

Indentation size effects in crystalline materials: a law for strain gradient plasticity. J Mech Phys Solids 1998; 46: 411–425.

29.

Torres

Hernández

Domínguez

Effect of antimony additions on corrosion and mechanical properties of Sn-Bi eutectic lead-free solder alloy. Mater Sci Appl 2012; 3: 355–362.

Experimental study and constitutive analysis of compressive creep behavior of solder material in IGBT modules

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