Using scanning acoustic microscopy and LM-BP algorithm for defect inspection of micro solder bumps

Micro solder bump has been widely used in electronic packaging. Currently a number of flip-chip products are developing towards miniaturization with more I/Os at finer pitch, and defect inspection of the high density package is increasingly challenging. In this paper, the Levenberg-Marquardt back-propagation network (LM-BP) combined with the scanning acoustic microscopy technology was investigated for intelligent diagnosis of solder defect. The flip chips were detected by using a 230 MHz ultrasonic transducer. Solder bumps were segmented from the SAM image. The statistical features were extracted and fed into the LM-BP networks for bump classification. The results demonstrate that LM-BP algorithm reached a high recognition accuracy, and is effective for defect inspection of the micro solder bump.     

Thermomechanical Reliability Study of Flip Chip Solder Bumps: Using Laser Ultrasound Technique and Finite Element Method

Current techniques for nondestructive quality evaluation of solder bumps in electronic packages are either incapable of detecting solder bump cracks, or unsuitable for in-line inspection due to high cost and low throughput. As an alternative, a solder bump inspection system is being developed at Georgia Institute of Technology using laser ultrasound and interferometric techniques . This system uses a pulsed Nd:YAG laser to induce ultrasound in electronic packages in the thermoelastic regime; it then measures the transient out-of-plane displacement responses on the package surfaces using laser interferometric technique. The quality of solder bumps in electronic packages is evaluated by analyzing the transient responses. This paper presents a systematic study on thermomechanical reliability of flip chip solder bumps using laser ultrasound–interferometric inspection technique and finite element (FE) method. The correlation between the failure parameter extracted from FE simulation for evaluating solder bump reliability and quality degradation characterization of solder bumps through noncontact, nondestructive laser ultrasound testing has also been investigated.      

Genetic algorithms for defect detection of flip chips

Flip chip packaging technology is widely used in high density assembly and superior performance devices. The solder joints are sandwiched between dies and substrates, leading to the defects optically opaque. Defect inspection of flip chips become more difficult. In this paper, a nondestructive detection method was presented. Ultrasonic excitations were forced on the surface of the flip chips and the raw vibration signals were measured by a laser scanning vibrometer. Eleven time domain features and twenty-four frequency domain features were extracted for analysis. After that, the genetic algorithm was introduced for feature selection and the back propagation network was adopted for classification and recognition. The flip chips were divided into three categories: good flip chips, flip chips with missing solder joints, and flip chips with open solder joints. They are recognized under the features selected by genetic algorithms rapidly and accurately, compared with those under other feature datasets, demonstrating that the approach using genetic algorithms is effective for defect inspection in flip chip packaging.     

Solder bump reliability-issues on bump layout

The reliability of solder bumps in a typical under-filled flip chip package is calculated three-dimensionally (3-D) using the finite element method and a viscoplastic material model for the solder. Simulations are performed with varying bump placement, underfill coverage and board size. The average plastic work in a bump is used to compare the loading and bump reliability of different geometries. The results show possible improvements over the traditional bump placement by changing the geometry of the interconnects on the flip chip package. Three changes that improve reliability are discussed in detail: the redistribution of bump rows, the reduction of board size and the inclusion of heat transfer bumps.     

The effect of solder bump pitch on the underfill flow

An underfill encapsulant was used to fill the gap between the chip and substrate around solder joints to improve the long-term reliability of flip chip interconnect systems. The underfill encapsulant was filled by the capillary effect. In this study, the filling time and pattern of the underfill flow in the process with different bumping pitch, bump diameter, and gap size were investigated. A modified Hele-Shaw flow model, that considered the flow resistance in both the thickness direction and the restrictions between solder bumps, was used. This model estimated the flow resistance induced by the chip and substrate as well as the solder bumps, and provided a reasonable flow front prediction. A modified model that considered the effect of fine pitch solder bumps was also proposed to estimate the capillary force in fine pitch arrangements. It was found that, on a full array solder bump pattern, the filling flow was actually faster for fine pitch bumps in some arrangements. The filling time of the underfill process depends on the parameters of bumping pitch, bump diameter, and gap size. A proposed capillary force parameter can provide information on bump pattern design for facilitating the underfilling process.     

Experimental characterization and mechanical behavior analysis of intermetallic compounds of Sn–3.5Ag lead-free solder bump with Ti/Cu/Ni UBM on copper chip

Due to today’s trend towards ‘green’ products, the environmentally conscious manufacturers are moving toward lead-free schemes for electronic devices and components. Nowadays the bumping process has become a branch of the infrastructure of flip chip bonding technology. However, the formation of excessively brittle intermetallic compound (IMC) between under bump metallurgy (UBM)/solder bump interface influences the strength of solder bumps within flip chips, and may create a package reliability issue. Based on the above reason, this study investigated the mechanical behavior of lead-free solder bumps affected by the solder/UBM IMC formation in the duration of isothermal aging. To attain the objective, the test vehicles of Sn–Ag (lead-free) and Sn–Pb solder bump systems designed in different solder volumes as well as UBM diameters were used to experimentally characterize their mechanical behavior. It is worth to mention that, to study the IMC growth mechanism and the mechanical behavior of a electroplated solder bump on a Ti/Cu/Ni UBM layer fabricated on a copper chip, the test vehicles are composed of, from bottom to top, a copper metal pad on silicon substrate, a Ti/Cu/Ni UBM layer and electroplated solder bumps. By way of metallurgical microscope and scanning-electron-microscope (SEM) observation, the interfacial microstructure of test vehicles was measured and analyzed. In addition, a bump shear test was utilized to determine the strength of solder bumps. Different shear displacement rates were selected to study the time-dependent failure mechanism of the solder bumps. The results indicated that after isothermal aging treatment at 150 °C for over 1000 h, the Sn–Ag solder revealed a better maintenance of bump strength than that of the Sn–Pb solder, and the Sn–Pb solder showed a higher IMC growth rate than that of Sn–Ag solder. In addition, it was concluded that the test vehicles of copper chip with the selected Ti/Cu/Ni UBMs showed good bump strength in both the Sn–Ag and Sn–Pb systems as the IMC grows. Furthermore, the study of shear displacement rate effect on the solder bump strength indicates that the analysis of bump strength versus thermal aging time should be identified as a qualitative analysis for solder bump strength determination rather than a quantitative one. In terms of the solder bump volume and the UBM size effects, neither the Sn–Ag nor the Sn–Pb solders showed any significant effect on the IMC growth rate.     

化学镀镍、模版印刷法制备倒扣芯片焊料凸点

回顾了低成本制备芯片上焊料凸点的方法,即化学镀镍制备凸点下金属层、模版印刷焊料,最后回流形成焊料凸点,并综述了该方法的最新研究进展.     

Effects of pre-bump probing and bumping processes on eutectic solder bump electromigration

This paper investigates the electromigration reliability of flip chip packages with and without pre-bump wafer probing via high temperature operation life test (HTOL) using printed and electroplated bumps. Under bump metallization (UBM) of printed and electroplated bumps is a thin film of Al/Ni(V)/Cu and Ti/Cu/Ni, respectively, while the bump material consists of eutectic Sn/Pb solder. Current densities from 7380 to 20 100 A/cm² and ambient temperatures at 100, 125 and 150 °C are applied in order to study their impact on electromigration. The results reveal that the bump temperature has a higher influence than the current density when it comes to bump failures. The observed interconnect damage is from bumps with electrical current flowing upward into the UBM/bump interface (cathode). Identified failure sites and modes reveal structural damage at the region of the UBM and UBM/bump interface, in the form of solder voiding and cracking. The effects of current polarity, current crowding, and operation temperature are key factors to electromigration failures of flip chip packaging. The maximum allowable current density of the electroplated bumps is superior to the printed bumps by a factor of 3.0–3.7 times. Besides, the median time to failure (MTTF) of without-underfill packaging is preferred to that of with-underfill packaging by 1.5–2.2 times. Furthermore, the differences in MTTF between pre-bump and without pre-bump probing procedures are 2.0–19.4% and 1.6–10.3% for printed and electroplated bumps, respectively.     

Defects pattern recognition for flip-chip solder joint quality inspection with laser ultrasound and Interferometer

A defects pattern recognition system has been developed for the flip-chip solder joint quality inspection by using laser ultrasound and interferometric techniques. This system extracts error ratio and dominant frequency as features from ultrasound waveforms. It also performs a cluster analysis of those feature vectors by applying probabilistic neural network classification algorithm. The system can automatically classify chips into different clusters and can, therefore, find differences between good and bad chips, as well as classifying the type of defect.     

Design of Solder Joint Structure for Flip Chip Package with an Optimized Shear Test Method

The structure of flip chip solder bumps was optimized in terms of shear height and shear speed using a shear test method with both experimental investigation and nonlinear, three-dimensional, finite element analysis being conducted. A representative, Pb-free solder composition, Sn-3.0Ag-0.5Cu, was used to optimize the shear test of the flip chip solder joints. Increasing the shear height, at a fixed shear speed, decreased the shear force, as did decreasing the shear speed, at a fixed shear height. These experimental and computational results supported the recommendation of low shear height and low shear speed condition for the shear testing of flip chip solder bumps. This optimized shear test method was applied to investigate the effect of various heights of mini bumps on the shear force of the solder joints. The shear force increased with increasing Ni-P mini bump height.     

Comparing the Impacts of the Capillary and the Molded Underfill Process on the Reliability of the Flip-Chip BGA

In the assembly process for the conventional capillary underfill (CUF) flip-chip ball grid array (FCBGA) packaging the underfill dispensing creates bottleneck. The material property of the underfill, the dispensing pattern and the curing profile all have a significant impact on the flip-chip packaging reliability. Due to the demand for high performance in the CPU, graphics and communication market, the large die size with more integrated functions using the low-K chip must meet the reliability criteria and the high thermal dissipation. In addition, the coplanarity of the flip-chip package has become a major challenge for large die packaging. This work investigates the impact of the CUF and the novel molded underfill (MUF) processes on solder bumps, low-K chip and solder ball stress, packaging coplanarity and reliability. Compared to the conventional CUF FCBGA, the proposed MUF FCBGA packaging provides superior solder bump protection, packaging coplanarity and reliability. This strong solder bump protection and high packaging reliability is due to the low coefficient of thermal expansion and high modulus of the molding compound. According to the simulation results, the maximum stress of the solder bumps, chip and packaging coplanarity of the MUF FCBGA shows a remarkable improvement over the CUF FCBGA, by 58.3%, 8.4%, and 41.8% (66 $mu {rm m}$), respectively. The results of the present study indicates that the MUF packaging is adequate for large die sizes and large packaging sizes, especially for the low-K chip and all kinds of solder bump compositions such as eutectic tin-lead, high lead, and lead free bumps.      

Anisotropic behavior of the capillary action in flip chip underfill

An underfill encapsulant can be used to improve the long-term reliability of flip chip interconnecting system by filling the gap between the chip and substrate around the solder bumps. The underfill encapsulant was filled by a capillary flow. This study was devoted to investigate the anisotropic effects of the capillary action induced by the solder bumps. A modified Hele-Shaw flow model, considering the flow resistance in both the thickness direction and the restrictions between solder bumps, was used. A capillary force model, depending on the direction of filling flow, for full array solder bumps was proposed. The capillary force was formulated based on quadrilateral arrangement of solder bumps. It was found that the capillary action is not the same for different directions. In the 45° direction, enhancement of the capillary flow was noticed for a bump pitch within a critical value. The edge preferential flow during the underfill experiment could be attributed to the anisotropic behavior of the capillary action.     

Reliability investigations of hard core solder bumps using mechanical palladium bumps and SnPb solder

The choice of solder joint metallurgy is a key issue especially for the reliability of flip-chip assemblies. Besides the metallurgical systems already widely used and well understood, new materials are emerging as solderable under bump metallization (UBM). For single chip bumping Pd stud bumps form a solid core under the solder layer. These hard core solder bumps are an adequate solution if single dies are available only and the chosen assembly technology is flip chip soldering. The scope of this paper is to summarize the results from aging of lead/tin solder bumps on palladium. The growth of intermetallic and its impact on the mechanical reliability are investigated.     

Experimental study of filling behaviors in the underfill encapsulation of a flip-chip

An underfill encapsulant was used to fill the gap between the chip and the substrate around the solder joints to improve the long-term reliability of the flip-chip interconnecting system. The underfill encapsulant was filled by the capillary effect. In this study, experiments were designed to investigate the effects of bump pitch and the edge detour flow on the underfill encapsulation. The bump array was patterned on a glass plate using the lithography technology. This patterned glass plate was used to simulate a flip-chip with solder bumps. The patterned glass was bounded to a substrate to form a simulated flip-chip system. With the lithography technology, it is easy to construct the test samples for underfill flow experiments with different configuration of solder bumps. It was observed that the filling flow was affected by the bump pitch. The edge detour flow depends mainly on the arrangement of the underfill dispensing process.     

A novel approach for flip chip solder joint quality inspection:laser ultrasound and interferometric system

A novel, noncontact, nondestructive approach for flip chip solder joint quality inspection is presented. In this technique, a pulsed laser generates ultrasound on the chip's surface, exciting the whole chip into a vibration motion. An interferometer was used to measure the vibration displacement of the chip's surface. Because changes in solder joint quality produce a different vibration response, a value, "error ratio," is used to measure the difference between a good chip and a chip with defects. An automatic signal-processing algorithm to calculate the error ratio was developed and implemented, as well as a frequency analysis algorithm. The inspection system was characterized, and results are presented for two cases of flip chips with missing solder balls. Results indicate that a laser ultrasonic/interferometeric system offers great promise for solder bump inspection in flip chip, BGA, chip scale, and micro BGA packages     

Single chip bumping and reliability for flip chip processes

Processes of bump deposition based on mechanical procedures together with their reliability data are summarized in this paper. The stud bumping of gold, palladium, and solder is described and also a novel bumping approach for fine pitch solder deposition down to 100 μm pitches using thermosonic bonding on a modified wedge–wedge bonding machine. This wedge bumping doesn’t require a wire flame-off process step. Because of this, no active atmosphere is necessary. The minimum pad diameter which can be bumped using the solder wedge bumping is 50 μm, up to now. This bumping process is highly reproducible and therefore well-suited for different flip chip soldering applications. Palladium stud bumps provide a solderable under bump metallization. Results from aging of lead/tin solder bumps on palladium are shown. The growth of intermetallics and its impact on the mechanical reliability are investigated.     

Bump formation for flip chip and CSP by solder paste printing

Area array packages (flip chip, CSP and BGA) require the formation of bumps for the board assembly. Since the established bumping methods need expensive equipment or are limited by the throughput, minimal pitch and yield the industry is currently searching for new and lower cost bumping approaches. In this paper the experimental work of stencil printing to create solder bumps for flip chip and wafer level CSP (CSP-WL) is described in detail.This paper is divided into two parts. In the first part of the paper a low cost wafer bumping process for flip chip applications will be studied in particular. The process is based on an electroless Nickel under bump metallization and solder bumping by stencil printing. The experimental results for this technology will be presented and the limits concerning pitch, reproducibility and bump height will be discussed in detail. The second part of the paper is focused on solder paste printing for wafer-level CSPs. In order to achieve large bumps an optimized printing method will be presented. Additionally advanced stencil design will be shown and the achieved results will be compared with conventional methods.     

Low cost bumping by stencil printing: process qualification for 200 μm pitch

Area array packages (flip chip, CSP (Chip scale packages) and BGA) require the formation of bumps for the board assembly. Since the established bumping methods need expensive equipment and/or are limited by the throughput, minimal pitch and yield, the industry is currently searching for new and lower cost bumping approaches. The experimental work of stencil printing to create solder bumps for flip chip devices is described in detail in this article. In the first part of this article, a low cost wafer bumping process for flip chip applications will be studied in particular. The process is based on an electroless nickel under bump metallization and solder bumping by stencil printing. The experimental results for this technology will be presented, and the limits concerning pitch, stencil design, reproducibility and bump height will be discussed in detail. In the second part, a comparison of measured standard deviations of bump heights as well as the quality demands for ultrafine pitch flip chip assembly are shown.     

Formation of Pb/63Sn solder bumps using a solder droplet jetting method

Formation processes of Pb/63Sn solder droplets using a solder droplet jetting have not been sufficiently reported. Solving problems such as satellite droplets and position errors are very important for a uniform bump size and reliable flip-chip solder bump formation process. First, this paper presents the optimization of jet conditions of Pb/63Sn solder droplets and the formation process of Pb/63Sn solder bumps using a solder droplet jetting method. Second, interfacial reactions and mechanical strength of jetted Pb/63Sn solder bumps and electroless Ni-P/Au UBM joints have been investigated. Interfacial reactions have been investigated after the second solder reflow and aging, and results were compared with those of solder bumps formed by a solder screen-printing method. Third, jetted solder bumps with variable bump sizes have been demonstrated by a multiple jetting method and the control of waveform induced to a jet nozzle. Multiple droplets jetting method can control various height and size of solder bumps. Finally, real applications of jetted Pb/63Sn solder bumps have been successfully demonstrated on conventional DRAM chips and integrated passive devices (IPDs).     

The microstructure characterization of ultrasmall eutectic Bi-Sn solder bumps on Au/Cu/Ti and Au/Ni/Ti under-bump metallization

The microstructure of the ultrasmall eutectic Bi-Sn solder bumps on Au/Cu/Ti and Au/Ni/Ti under-bump metallizations (UBMs) was investigated as a function of cooling rate. The ultrasmall eutectic Bi-Sn solder bump, about 50 μm in diameter, was fabricated by using the lift-off method and reflowed at various cooling rates using the rapid thermal annealing system. The microstructure of the solder bump was observed using a backscattered electron (BSE) image and the intermetallic compound was identified using energy dispersive spectroscopy (EDS) and an x-ray diffractometer (XRD). The Bi facet was found at the surface of the ultrasmall Bi-Sn solder bumps on the Au/Cu/Ti UBM in almost all specimens, and the interior microstructure of the bumps was changed with the solidification rate. The faceted and polygonal intermetallic compound was found in the case of the Bi-Sn solder bump on the Au (0.1 μm)/Ni/Ti UBM, and it was confirmed to be the (Au_1−x−yBi_xNi_y)Sn₂ phase by XRD. The intermetallic compounds grown form the Au (0.1 μm)/Ni/Ti UBM interface, and they interrupted the growth of Bi and Sn phases throughout the solder bump. The ultrasmall eutectic Bi-Sn solder bumps on the Au (0.025 μm)/Ni/Ti UBM showed similar microstructures to those on the Au/Cu/Ti UBM.