Solder joint failures under thermo-mechanical loading conditions – A review

ABSTRACT

Solder joints play a critical role in electronic devices by providing electrical, mechanical and thermal interconnections. These miniature joints are also the weakest links in an electronic device. Under severe thermal and mechanical loadings, solder joints could fail in ‘tensile fracture, fatigue failure and creep failure. This paper reviews the literature on solder joint failures under thermo-mechanical loading conditions, with a particular emphasis on fatigue and creep failures. Literature reviews mainly focused on commonly used lead-free Sn-Ag-Cu (SAC) solders. Based on the literature in experimental and simulation studies on solder joints, it was found that fatigue failures are widely induced by accelerated thermal cycling (ATC). During ATC, the mismatch in coefficients of thermal expansion (CTE) between different elements of electronics assembly contributes significantly to induce thermal stresses on solder joints. The fatigue life of solder joints is predicted based on phenomenological fatigue models that utilise materials properties as inputs. A comparative study of 14 different fatigue life prediction models is presented with their relative advantages, scope and limitations. A critical review of various creep models is presented. Finally, the paper outlined the combined effect of creep and fatigue on solder joint failure.

KEYWORDS:

• Solder joint
• creep failure
• fatigue failure
• thermal cycling
• thermal ageing

Acknowledgments

The authors gratefully acknowledge the PhD funding contributions of University of Derby.

Disclosure statement

No potential conflict of interest was reported by the authors.