BGA焊点在板级跌落实验中的疲劳寿命估计

按照JEDEC标准对板级跌落实验的要求测试了有铅和无铅焊点的球栅阵列封装.用ANSYS软件建立了有限元分析模型,并用ANSYS/LS-DYNA直接求解器计算了典型结点的应力和应变,以及每次跌落时积累在焊点中的平均应变能密度.利用实验和模拟的结果重新计算了Darveaux模型中的常数,将这个模型的应用范围扩展到了跌落环境,并计算了各种条件下焊点的疲劳寿命.     

Random vibration reliability of BGA lead-free solder joint

Solder joint fatigue failure under vibration loading has been a great concern in microelectronic industry. High-cycle fatigue failure of lead-free solder joints has not been adequately addressed, especially under random vibration loading. This study aims to understand the lead-free solder joint behavior of BGA packages under different random vibration loadings. At first, non-contact TV Laser holography technology was adopted to conduct experimental modal analysis of the test vehicle (printed circuit board assembly) in order to understand its dynamic characteristics. Then, its first order natural frequency was used as the center frequency and narrow-band random vibration fatigue tests with different kinds of acceleration power spectral density (PSD) amplitudes were respectively carried out. Electrical continuity through each BGA package is monitored during the vibration event in order to detect the failure of package-to-board interconnects. The typical dynamic voltage histories of failed solder joints were obtained simultaneously. Thirdly, failed solder joints were cross-sectioned and metallurgical analysis was applied to investigate the failure mechanisms of BGA lead-free solder joints under random vibration loading. The results show that the failure mechanisms of BGA lead-free solder joint vary as the acceleration PSD amplitude increases. Solder joint failure locations are changed from the solder bump body of the PCB side to the solder ball neck, finally to the Ni/intermetallic compound (IMC) interface of the package side. The corresponding failure modes are also converted from ductile fracture to brittle fracture with the increase of vibration intensity.     

银含量对随机振动条件下无铅焊点可靠性的影响

为了探究银含量对无铅焊点在随机振动条件下的可靠性的影响,对Sn-3.0Ag-0.5Cu、Sn-1.0Ag-0.5Cu和Sn-0.3Ag-0.7Cu三种不同Ag含量材料的焊点做窄带范围内的随机振动疲劳实验,并对失效焊点进行分析。结果表明:三种材料焊点的失效位置基本都在靠近PCB侧,最外围焊点最容易失效,失效模式均为脆性断裂,并且随着Ag含量的降低,金属间化合物的厚度逐渐减小,焊点的疲劳寿命逐渐延长。     

Board level drop test and simulation of leaded and lead-free BGA-PCB assembly

Leaded and lead-free ball grid array (BGA) components were tested in board level drop test defined in the Joint Electron Device Engineering Council (JEDEC) standard under different load levels. Finite element analysis (FEA) models were established using ANSYS. The stress and strain in the solder joint and the average strain energy density (SED) in the solder–pad interface accumulated in one cycle were calculated using ANSYS/LS-DYNA explicit solver. The results of experiment and simulation were employed to re-calculate the constants contained in the Darveaux model to extend its application to the drop test. Then, FEA models with different height and pitch of solder joints were established to obtain the SED to calculate the fatigue life of solder joint under different geometrical conditions through this modified model. The experiment and simulation reveal that the failures mainly occur in the solder–PCB interface in lower load level, the other way round, in a higher load level, the cracks are more possibly formed in solder–package interface; comparing to dropping in horizontal direction with package faces down, the solder joints are much harder to fail when dropping in vertical direction; An optimal height and smaller pitch of solder joints lead to lowest SED and best reliability in the drop test.     

Board level solder joint reliability modeling and testing of TFBGA packages for telecommunication applications

For thin-profile fine-pitch BGA (TFBGA) packages, board level solder joint reliability during the thermal cycling test is a critical issue. In this paper, both global and local parametric 3D FEA fatigue models are established for TFBGA on board with considerations of detailed pad design, realistic shape of solder joint, and nonlinear material properties. They have the capability to predict the fatigue life of solder joint during the thermal cycling test within ±13% error. The fatigue model applied is based on a modified Darveaux’s approach with nonlinear viscoplastic analysis of solder joints. A solder joint damage model is used to establish a connection between the strain energy density (SED) per cycle obtained from the FEA model and the actual characteristic life during the thermal cycling test. For the test vehicles studied, the maximum SED is observed at the top corner of outermost diagonal solder ball. The modeling predicted fatigue life is first correlated to the thermal cycling test results using modified correlation constants, curve-fitted from in-house BGA thermal cycling test data. Subsequently, design analysis is performed to study the effects of 14 key package dimensions, material properties, and thermal cycling test condition. In general, smaller die size, higher solder ball standoff, smaller maximum solder ball diameter, bigger solder mask opening, thinner board, higher mold compound CTE, smaller thermal cycling temperature range, and depopulated array type of ball layout pattern contribute to longer fatigue life.     

Board level solder joint reliability analysis of stacked die mixed flip-chip and wirebond BGA

Stacked die BGA has recently gained popularity in telecommunication applications. However, its board level solder joint reliability during the thermal cycling test is not as well-studied as common single die BGA. In this paper, solder joint fatigue of lead-free stacked die BGA with mixed flip-chip (FC) and wirebond (WB) interconnect is analyzed in detail. 3D fatigue model is established for stacked die BGA with considerations of detailed pad design, realistic shape of solder ball, and non-linear material properties. The fatigue model applied is based on a modified Darveaux’s approach with non-linear viscoplastic analysis of solder joints. Based on the FC–WB stack die configuration, the critical solder ball is observed located between the top and bottom dice corner, and failure interface is along the top solder/pad interface. The modeling predicted fatigue life is first correlated to the thermal cycling test results using modified correlation constants, curve-fitted from in-house lead-free TFBGA46 (thin-profile fine-pitch BGA) thermal cycling test data. Subsequently, design analyzes are performed to study the effects of 20 key design variations in package dimensions, material properties, and thermal cycling test conditions. In general, thinner PCB and mold compound, thicker substrate, larger top or bottom dice sizes, thicker top die, higher solder ball standoff, larger solder mask opening, smaller PCB pad size, smaller thermal cycling temperature range, longer ramp time, and shorter dwell time contribute to longer fatigue life. SnAgCu is a common lead-free solder, and it has much better board level reliability performance than eutectic solder based on modeling results, especially low stress packages.     

热循环加载片式元器件带空洞无铅焊点的可靠性

建立了片式元器件带空洞无铅焊点有限元分析模型,研究了热循环加载条件下空洞位置和空洞面积对焊点热疲劳寿命的影响.结果表明:热循环加载条件下空洞位置和空洞面积显著影响焊点热疲劳寿命.空洞位置固定于焊点中部且面积分别为7.065×10-4,1.256×10-3,1.963×10-3和2.826×10-3mm2时,焊点热疲劳寿...     

Impact of laminate cracks under solder pads on the fatigue lives of ball grid array solder joints

This paper reports how the solder joint fatigue lives of three types of lead free plastic BGA components were affected by cracks formed in the printed PCB laminate during a thermal cycling test. The investigation showed that cracks were formed in the laminate for all three tested components. For one of the components having a large chip with solder joints located under the chip, very large cracks were formed in the PCB laminate beneath some solder pads.For lead-free solder joints to BGA components consisting of near eutectic solders based on tin, silver and copper, a large fraction of the solder joints may consist of one single tin grain. Due to anisotropy of tin grains, each solder joint to a BGA component will experience a unique stress condition which will make laminate cracking more likely under certain solder joints.The laminate cracks increased the flexibility of the joints and thereby improved the fatigue lives of the solder joints. Therefore, an estimation of the fatigue lives of solder joints to BGA components based on the results from a thermal cycling test may lead to an overestimation of the fatigue lives if products will be exposed to smaller temperature changes in the field than in the test.If cracks are not formed in the PCB laminate, or if the extent of cracking is small, single-grained solder joints can be expected to result in a high spread in failure distribution with some quite early failures.     

Investigation of mechanical shock testing of lead-free SAC solder joints in fine pitch BGA package

The lead-free Sn-Ag-Cu (SAC 305/405) solder that replaced the tin-lead eutectic solder tends to be more brittle in nature due to high stiffness and excessive solder interfacial reactions. This leads to higher occurrences of solder joints failure during surface mount assembly and handling operations as a result of PCB bending, shock impact and drop. In this work, mechanical tests simulating the shock impact were conducted on lead-free SAC of different weight percentages. These SAC materials were prepared for use in the solder joints of fine pitch ball grid array (BGA) components which were mounted onto the motherboard. After the mechanical shock tests, strain measurements were performed on the BGA components to gauge the solder joint integrity, which was shown to be related with the formation of intermetallics in the bulk and at the interface of the SAC solder. The ball pull tests were conducted to determine both the bulk and interfacial strength and the solder joint fracture, which was classified as either mode 1, 2 or 3. A correlation was made between the silver (Ag) and copper (Cu) weight percentages with the metallurgical reactions.     

Effect of process-induced voids on isothermal fatigue resistance of CSP lead-free solder joints

With the progressive miniaturization of electronic devices, process-induced voids in lead-free solder joints affect the assessment of thermal fatigue resistance. Voids appear randomly in a solder joint, making quantitative evaluation of fatigue life difficult. This study examined the effect of process-induced voids on the thermal fatigue resistance of CSP solder joints. CSP specimens were subjected to isothermal mechanical fatigue tests; specifically, the accelerated thermal cycle test. When a void is small, it has no apparent effect on fatigue life. However, when voids having diameters of at least 30% of solder diameter are located along the crack propagation route, fatigue life is shortened. FEA and Miner’s law for estimation of fatigue life suggest that voids affect not only the crack initiation but also crack propagation. Estimated numbers of cycles to failure agree quantitatively with the experimental results. The effects of the size, location, and number of voids can be extracted by FEA. As voids along the crack path become larger, fatigue life decreases. Moreover, when two voids are located near the corner of a solder joint on the crack path, a 30% decrease in life appears. This result agrees with experimental results reported in several literatures.     

Impact of temperature cycle profile on fatigue life of solder joints

In this paper the influence of the temperature cycle time history profile on the fatigue life of ball grid array (BGA) solder joints is studied. Temperature time history in a Pentium processor laptop computer was measured for a three-month period by means of thermocouples placed inside the computer. In addition, Pentium BGA packages were subjected to industry standard temperature cycles and also to in-situ measured temperature cycle profiles. Inelastic strain accumulation in each solder joint during thermal cycling was measured by high sensitivity Moire interferometry technique. Results indicate that fatigue life of the solder joint is not independent of the temperature cycle profile used. Industry standard temperature cycle profile leads to conservative fatigue life observations by underestimating the actual number of cycles to failure.     

湿热环境下倒装焊无铅焊点的可靠性

对板上倒装芯片底充胶进行吸湿实验,并结合有限元分析软件研究了底充胶在湿敏感元件实验标准MSL—1条件下吸湿和热循环阶段的解吸附过程,测定了湿热环境对Sn3.8Ag0.7Cu焊料焊点可靠性的影响,并用蠕变变形预测了无铅焊点的疲劳寿命。结果表明:在湿热环境下,底充胶材料内部残留的湿气提高了焊点的应力水平。当分别采用累积蠕变应变和累积蠕变应变能量密度寿命预测模型时,无铅焊点的寿命只有1740和1866次循环周期。     

Board level reliability of PBGA using flex substrate

Assurance of board level reliability is necessary and required for adopting any new packages into products. This paper presents board level reliability test results of a flex substrate BGA under thermal and bend cyclic tests. It is well known that solder joint reliability is affected by many factors, such as the size of chip, joint stand-off height, pad design, test board surface finish, substrate gold plating thickness and the utilization of underfill material, etc. However, most of the works have been conducted are BGA on rigid substrates. In this work, thermal cyclic test is performed to re-examine these factors using package housed on a flex substrate. Bending test with two deflections is also performed to investigate solder joint fatigue life and failure modes under mechanically repetitive loading.Two-parameter Weibull model is used to analyze joint fatigue life. Failure analysis is conducted and discussed for each case. Under temperature cycling test, chip size, polyimide thickness and underfill material utilization were found to have significant impacts on joint fatigue life, especially the effect of applying underfill material to the joint. Epoxy thickness was found to have little effect on the joint fatigue life for this case.The effects of test board surface finish and substrate gold plating thickness on the joint fatigue life were found coupled. The term “substrate” here refers to the chip carrier, while the “board” here refers to motherboard, which is the board to assemble test vehicles on. The gold thickness here all refers to the electrolytic gold plating on the substrate. Using organic solderability preservative boards, substrate gold plating thickness affects joint fatigue life slightly, but with Au–Ni test boards, the effect is tremendous. The difference is due to different intermetallic compounds (IMC) formed. In other words, different IMC systems are formed due to different combination of test board surface finish and substrate gold plating thickness. As a result, different IMC induces different failure modes. The joint fatigue life under cyclic bend test with different deflections is also probed and shown. The corresponding failure modes are also discussed.     

Torsion test applied for reballing and solder paste volume evaluation

Electronic second level interconnect reliability characterization by accelerated thermal-cycling (ATC) test for long-term mission profile is costly and high time consuming. In order to reduce test duration, the torsion test was applied using some specific test parameters to reproduce the same failure modes found in accelerated thermal cycling (ATC) test and in the field. In this paper, we present the torsion test parameters definition and two demonstrations of torsion test application to accelerate reliability characterization of second level interconnect. The first application is the comparison between full SnPb (tin–lead) and reballed LF (lead-free) packages using SnPb balls. In the second the reliability of ceramic BGA solder joints using different solder paste volume was evaluated. In both cases, ATC test results were used as reference. The results suggest that torsion test is a valuable test method and can be applied to evaluate the impact of design and process variations in very short time.     

用真空再流焊实现BGA的无铅无空洞焊接

BGA焊接后常常会在焊点中形成很多的空洞,特别是对于BGA的无铅焊接,由于焊接温度高,氧化严重,以及焊料的特殊性能决定了BGA的无铅焊接更容易形成空洞.空洞的产生不仅影响焊点的导热、导电性能,也会影响焊点的强度,从而对BGA工作的长期可靠性产生影响.分析了空洞产生的机理,以及用真空再流焊接实现BGA无铅、无空洞焊接的原理和工艺过程.指出真空再流焊接工艺在解决BGA的无铅、无空洞化焊接问题上确实是一项行之有效的方法.     

A review of board level solder joints for mobile applications

The reliability of electronics under drop-shock conditions has attracted significant interest in recent years due to the widespread use of mobile electronic products. This review focuses on the drop-impact reliability of lead-free solder joints that interconnect the integrated circuit (IC) component to the printed circuit board (PCB). Major topics covered are the physics of failure in drop-impact; the use of board level and component level test methods to evaluate drop performance; micro-damage mechanisms; failure models for life prediction under drop-impact; modelling and simulation techniques; and dynamic stress–strain properties of solder joint materials. Differential bending between the PCB and the IC component is the dominant failure driver for solder joints in portable electronics subjected to drop-impact. Board level drop-shock tests correlate well with board level high speed cyclic bending tests but not with component level ball impact shear tests. Fatigue is the micro-damage mechanism responsible for the failure of solder joints in the drop-shock of PCB assemblies and the fatigue strength of solder joints depends strongly on the strain rate, test temperature, and the sequence of loading. Finally, tin-rich lead-free solders exhibit significantly higher strain rate sensitivity than eutectic SnPb solder.     

Low cycle fatigue performance of ball grid array structure Cu/Sn–3.0Ag–0.5Cu/Cu solder joints

Low cycle fatigue performance of ball grid array (BGA) structure Cu/Sn–3.0Ag–0.5Cu/Cu joints with different standoff heights (h, varying from 100 to 500 μm) and two pad diameters (d, d = 320 and 480 μm) under displacement-controlled cyclic loading was studied by experimental method and finite element (FE) simulation. A prediction method based on the plastic strain energy density and continuum damage mechanics (CDM) framework was proposed to evaluate the initiation and propagation of fatigue crack in solder joints. The results show that fatigue failure of solder joints is a process of damage accumulation and the plastic strain energy density performs a power function correlation with the cycle numbers of crack initiation and propagation. Crack propagation rate is affected by the stress triaxiality, which is dependent on the loading mode and increases dramatically with decreasing h under tensile loading, while the change of standoff height has very limited influence on the stress triaxiality under shear loading mode. Moreover, crack growth correlation constants identified in Cu/Sn–3.0Ag–0.5Cu/Cu joints with a specific geometry (h = 100 μm and d = 480 μm) can be well used to predict the fatigue life of BGA joints with other geometries. Furthermore, the results have also shown that the fatigue life of solder joints increases with decreasing the geometric ratio of h/d under the same nominal shear strain amplitude, while it drops with decreasing h/d under the same shear displacement amplitude in cyclic loading. When the geometric ratio (i.e., h/d ratio) is unchanged, the miniaturization of BGA joints brings about a decrease in fatigue life of the joints.     

Finite element based fatigue life estimation of the solder joints with effect of intermetallic compound growth

This paper develops an analysis procedure to study the effects of intermetallic compound (IMC) growth on the fatigue life of 63Sn-37Pb (lead-rich)/96.5Sn-3.5Ag (lead-free) solder balls for flip-chip plastic ball grid array packages under thermal cycling test conditions. In this analysis procedure, the thickness of the IMC increased with the number of thermal cycles, and was determined using the growth rate equation. A series of non-linear finite element analyses was conducted to simulate the stress/strain history at the critical locations of the solder balls with various IMC thicknesses in thermal cycling tests. The simulated stress/strain results were then employed in a fatigue life prediction model to determine the relationship between the predicted fatigue life of the solder ball and the IMC thickness. Based on the concept of continuous damage accumulation and incorporated with the linear damage rule, this study defines the damage of each thermal cycle as the reciprocal of the predicted fatigue life of the solder joints with the corresponding IMC thickness. The final fatigue failure of the solder ball was determined as the number of cycles corresponding to the cumulative damage equal to unity. Results show that the solder joint fatigue life decreased as the IMC thickness increased. Moreover, the predicted thermal fatigue life of lead-rich solders based on the effects of IMC growth is apparently smaller than that without considering the IMC growth in the reliability analysis. Results also show that the influence of the IMC thickness on the fatigue life prediction of the lead-free solder joint can be ignored.     

热循环参数及基板尺寸对焊点可靠性的影响

采用Ansys软件建立BGA倒装芯片模型考察焊点的热应力。通过改变热循环保温时间、温度范围和最高温度,研究各参数对焊点热疲劳寿命的影响,同时也考察了基板的长度和厚度的影响。采用Coffin-Manson方程计算并比较热循环寿命。结果表明:随着热循环高低温停留时间、温度范围以及最高热循环温度的增大,热循环寿命减小,最小寿命为879周;同时热循环寿命也随着基板长度和厚度的增大而减小。     

Flip chip solder joint reliability analysis using viscoplastic and elastic-plastic-creep constitutive models

Both elastic-plastic-creep and viscoplastic constitutive models may be used for inelastic deformation analysis of solder joints. In this paper, a phenomenological approach using elastic-plastic-creep analysis and an Anand viscoplastic model is reported for solder joint reliability. Flip chip soldered assemblies with 63Sn-37Pb solder joints were subjected to a thermal cyclic loading condition of -40 to +125/spl deg/C to assess the solder joint fatigue performance. In the finite-element modeling, the viscoplastic strain energy density per cycle obtained from the viscoplastic analysis is compared with the inelastic (plastic and creep) strain energy density per cycle calculated from the elastic-plastic-creep analysis. The inelastic (plastic+creep and viscoplastic) strain energy density extracted from the finite-element analysis results, at the critical solder joint location, were used as a failure parameter for solder fatigue models employed. It was found that the predicted solder joint fatigue life has a better correlation to the first failure or first-time-to-failure result.