Lead‐free solder joint reliability estimation of flip chip package using FEM‐based sensitivity analysis

The purpose of the present study is to investigate the melting properties, microstructures, tensile properties and fatigue properties of Sn 5Sb(0.050.50)Ni (mass%) high-temperature lead-free solders. The solidus temperature and liquidus temperature of the Sn5SbNi solders are approximately equal to those of the Sn5Sb alloy. From the result of EPMA mapping analysis and the SnSbNi ternary phase diagram, the Sn 5SbNi solders are found to consist of ¢-Sn, SbSn and NiSb phases. As the amount of Ni in the Sn5SbNi solder increases, the number of NiSb phases increases and the phases are coarsened so that the 0.1% proof stress and tensile strength increase, and the elongation decreases at 25°C. In contrast, the effects of the Ni content on the tensile properties are negligible at 150°C and 200°C. The fatigue ductility exponent ¡ of the Sn 5SbNi solders is smaller than that of the Sn5Sb solder at 25°C. At 150°C and 200°C, the ¡ values of Sn5Sb0.05Ni and Sn5Sb0.10Ni remain small, whereas those of Sn5Sb0.25Ni and Sn5Sb0.50Ni increase. This means that the Sn5SbNi solders with 0.050.10 mass% Ni have superior fatigue properties to the Sn5Sb solder in the temperature range from 25°C to 200°C.

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“…In general, the low-cycle fatigue life of a metal obeys the MansonCoffin equation as follows: 21,22)…”

Section: Fatigue Propertiesmentioning

confidence: 99%

Effects of Ni Addition to Sn–5Sb High-Temperature Lead-Free Solder on Its Microstructure and Mechanical Properties

2019

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“…Related work was undertaken by Lee et al [74,77], Weertman [75] and Herring [76]. Weertman [75] and Wong et al [78] examined the creepfatigue models of solder joints. They reviewed creep-fatigue models in the aerospace and power electronics.…”

Section: Creep Failure Of Solder Jointsmentioning

confidence: 99%

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

Depiver

Mallik

Harmanto

2020

Advances in Materials and Processing Technologies

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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' due to stress overloading, 'fatigue failure' because of the application of cyclical stress and 'creep failure' due to a permanent long-term load. 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 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. Creep failures in solder joints, on the other hand, are commonly induced through isothermal ageing. A critical review of various creep models is presented. Many of these strain ratebased creep models are routed to very well-known Anand Model of inelastic strain rate. Finally, the paper outlined the combined effect of creep and fatigue on solder joint failure.

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“…where C is the fatigue ductility factor, ∆ε in is the inelastic strain range, N f is the number of cycles to failure, and α is the fatigue ductility exponent. It has known that the low-cycle fatigue life of solder alloys generally obeys the Manson-Coffin equation [22][23][24][25]. Figure 13 shows the relationship between the inelastic strain range and the number of cycles to failure of the Sn-10Sb and Sn-10Sb-Ni with 0.05-0.50 mass% Ni specimens plotted on the double logarithm.…”

Section: Fatigue Properties and Microstructural Changementioning

confidence: 99%

Evaluation of Microstructures and Mechanical Properties of Sn-10Sb-Ni Lead-Free Solder Alloys with Small Amount of Ni Using Miniature Size Specimens

Kobayashi

Shohji

2019

Metals

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Sn-Sb-Ni solder alloy is expected to be used as a die-attach material for a next-generation power semiconductors in power module. The aim of this paper is to investigate the effects of the Ni content on microstructures, tensile, and fatigue properties of Sn-10Sb-xNi (x = 0.05, 0.10, 0.25, 0.50) (mass%) lead-free solder alloys using miniature size specimens. The Sn-10Sb-Ni solder alloys have the microstructure in which Sb-Sn and Ni-Sb compounds are dispersed in the β-Sn matrix. As the Sb and Ni content increases, Sb-Sn and Ni-Sb compounds are coarsened, respectively. The effect of the Ni content on tensile properties of the alloy is slight at 25 °C. At 150 °C and 200 °C, 0.1% proof stress and tensile strength increase gradually with the Ni content increases, and saturate at the Ni amount over 0.25 mass%. According to the fatigue test at 200 °C, the fatigue properties of Sn-10Sb-Ni with 0.10–0.25 mass% Ni are better than that of the Sn-10Sb. From the experimental results, Sn-10Sb-Ni with 0.10–0.25 mass% Ni have superior mechanical properties.

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Lead‐free solder joint reliability estimation of flip chip package using FEM‐based sensitivity analysis

Cited by 11 publications

References 21 publications

Effects of Ni Addition to Sn–5Sb High-Temperature Lead-Free Solder on Its Microstructure and Mechanical Properties

Effects of Ni Addition to Sn–5Sb High-Temperature Lead-Free Solder on Its Microstructure and Mechanical Properties

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

Evaluation of Microstructures and Mechanical Properties of Sn-10Sb-Ni Lead-Free Solder Alloys with Small Amount of Ni Using Miniature Size Specimens

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