Process Characteristics of 100μm Bump Pitch with Lead-Free and High Lead Plating Solder Bump

2006 ◽  
Author(s):  
R. Yu ◽  
J.-I. Yu ◽  
T. Tai ◽  
C.H. Kang ◽  
J. Chen ◽  
...  
Keyword(s):  
Solder Bump ◽  
Lead Free ◽  
Process Characteristics ◽  
High Lead

Quantitative Evaluation of Voids in Lead Free Solder Joints

2015 ◽  
Vol 772 ◽  
pp. 284-289 ◽  
Author(s):  
Sabuj Mallik ◽  
Jude Njoku ◽  
Gabriel Takyi
Keyword(s):  
Solder Bump ◽  
Solder Joints ◽  
Void Formation ◽  
Lead Free ◽  
Lead Free Solder ◽  
Solder Paste ◽  
X Ray ◽  
Size And Shape ◽  
Solder Bumps ◽  
Free Solder

Voiding in solder joints poses a serious reliability concern for electronic products. The aim of this research was to quantify the void formation in lead-free solder joints through X-ray inspections. Experiments were designed to investigate how void formation is affected by solder bump size and shape, differences in reflow time and temperature, and differences in solder paste formulation. Four different lead-free solder paste samples were used to produce solder bumps on a number of test boards, using surface mount reflow soldering process. Using an advanced X-ray inspection system void percentages were measured for three different size and shape solder bumps. Results indicate that the voiding in solder joint is strongly influenced by solder bump size and shape, with voids found to have increased when bump size decreased. A longer soaking period during reflow stage has negatively affectedsolder voids. Voiding was also accelerated with smaller solder particles in solder paste.

Evaluation of Emerging High Melting Point Lead-free Solder and Hybrid Sinter Paste as Attaching Material for Clip Bond Package

2020 ◽  
Vol 2020 (1) ◽  
pp. 000235-000241
Author(s):  
Fred Fuliang Le ◽  
Rinse van der Meulen ◽  
Yoon Kheong Leong ◽  
Manoj Balakrishnan ◽  
Zunyu Guan
Keyword(s):  
Melting Point ◽  
Lead Free ◽  
Lead Free Solder ◽  
Reliability Testing ◽  
High Melting ◽  
High Melting Point ◽  
Basic Scheme ◽  
Free Solder ◽  
Lead Free Solders ◽  
High Lead

Abstract High melting point (HMP) lead-free solder, hybrid sinter and transient liquidus phase sinter (TLPS) are the emerging lead-free alternatives for the potential replacement of high-lead solder. Lead-free solder is perfectly compatible with existing high-lead soldering processes for clip bond packages. The benefit of hybrid sinter is that it has much higher thermal and electrical conductivity than lead-free or high-lead solder. In this study, ten materials (including lead-free solders, hybrid sinter paste and TLPS) were first evaluated via die shear test. With the initial material screening, two lead-free solders (solder 1 and 2), two hybrid Ag sinter pastes (sinter i and ii) and one TLPS proceeded to internal sample assembly. For the lead-free solders, a process optimization with the aid of vacuum reflow was made to reduce void rate. Due to the slow and unbalanced inter-diffusion of Ag-Cu sintering than Ag-Ag sintering, optimizations to enhance the hybrid Ag sintering include Ag finishing for the die metallization and Ag plating for the clip and bond area of the leadframe. In 0-hour package electrical test, solder 1 and sinter i passed and were sent for reliability testing while solder 2, sinter ii and TLPS failed due to intermetallic compound (IMC) cracking, material bleeding and die cracking, respectively. In the reliability testing, a basic scheme of thermal cycling (TC) 1000 cycles, intermittent operating life (IOL) 750 hrs and highly accelerated temperature and humidity stress test (HAST) 96 hrs was defined for the early feasibility study. 1 of 75 sinter i units failed by TC 1000 cycles due to separation between silver sinter structure and die bottom metallization. Solder 1 passed the basic scheme without defects, and next the material workability and clip bond strength need to be improved to the equivalent level of high-lead solders.

Epoxy Underfill Challenges for Copper (Cu) Pillar Solder Bump Packages

2014 ◽  
Vol 2014 (1) ◽  
pp. 000247-000250
Author(s):  
Brian Schmaltz ◽  
Yukinari Abe ◽  
Kazuyuki Kohara
Keyword(s):  
Thermal Cycling ◽  
Solder Ball ◽  
Solder Bump ◽  
High Density ◽  
Lead Free ◽  
Reflow Process ◽  
Stress Concentrations ◽  
Cu Pillar ◽  
Advanced Packaging ◽  
Capillary Underfill

From Eutectic, to Lead Free, to Copper Pillar (Cu) Bumping Technologies. As technology progresses to smaller process generations, new packaging applications are being demanded. The standard solder ball reflow process is being pushed by advancements in copper pillar capped bumps, which in turn allows for high density lead free IO counts at sub 40um bump pitches. Even so, low CTE epoxy materials are still needed in order to dissipate stress concentrations seen during thermal cycling. What challenges await this next technological revision? This presentation will centralize around the latest advancements in epoxy materials for Advanced Packaging Technology; Capillary Underfill (CUF) for narrow pitch Lead Free Copper (Cu) Pillar Solder Bump packages.

Electromigration Performance of Flip-Chips with Lead-Free Solder Bumps between 30 μm and 60 μm Diameter

2012 ◽  
Vol 2012 (1) ◽  
pp. 000891-000905 ◽  
Author(s):  
Rainer Dohle ◽  
Stefan Härter ◽  
Andreas Wirth ◽  
Jörg Goßler ◽  
Marek Gorywoda ◽  
...  
Keyword(s):  
Flip Chip ◽  
Failure Modes ◽  
Solder Bump ◽  
Void Formation ◽  
Lead Free ◽  
Large Temperature ◽  
Flip Chips ◽  
Solder Bumps ◽  
Current Densities

As the solder bump sizes continuously decrease with scaling of the geometries, current densities within individual solder bumps will increase along with higher operation temperatures of the dies. Since electromigration of flip-chip interconnects is highly affected by these factors and therefore an increasing reliability concern, long-term characterization of new interconnect developments needs to be done regarding the electromigration performance using accelerated life tests. Furthermore, a large temperature gradient exists across the solder interconnects, leading to thermomigration. In this study, a comprehensive overlook of the long-term reliability and analysis of the achieved electromigration performance of flip-chip test specimen will be given, supplemented by an in-depth material science analysis. In addition, the challenges to a better understanding of electromigration and thermomigration in ultra fine-pitch flip-chip solder joints are discussed. For all experiments, specially designed flip-chips with a pitch of 100 μm and solder bump diameters of 30–60 μm have been used [1]. Solder spheres can be made of every lead-free alloy (in our case SAC305) and are placed on a UBM which has been realized for our test chips in an electroless nickel process [2]. For the electromigration tests within this study, multiple combinations of individual current densities and temperatures were adapted to the respective solder sphere diameters. Online measurements over a time period up to 10,000 hours with separate daisy chain connections of each test coupon provide exact lifetime data during the electromigration tests. As failure modes have been identified: UBM consumption at the chip side or depletion of the Nickel layer at the substrate side, interfacial void formation at the cathode contact interface, and - to a much lesser degree - Kirkendall-like void formation at the anode side. A comparison between calculated life time data using Weibull distribution and lognormal distribution will be given.

Thermally Activated Bumping Process using Sn3.0Ag0.5Cu Solder Powder for Low-Cost Interposers

2013 ◽  
Vol 2013 (1) ◽  
pp. 000420-000423
Author(s):  
Kwang-Seong Choi ◽  
Ho-Eun Bae ◽  
Haksun Lee ◽  
Hyun-Cheol Bae ◽  
Yong-Sung Eom
Keyword(s):  
Screen Printing ◽  
Flip Chip ◽  
Solder Bump ◽  
Low Cost ◽  
Organic Substrate ◽  
Lead Free ◽  
Lead Free Solder ◽  
Thermally Activated ◽  
Fine Pitch ◽  
Free Solder

A novel bumping process using solder bump maker (SBM) is developed for fine-pitch flip chip bonding. It features maskless screen printing process with the result that a fine-pitch, low-cost, and lead-free solder-on-pad (SoP) technology can be easily implemented. The process includes two main steps: one is the thermally activated aggregation of solder powder on the metal pads on a substrate and the other is the reflow of the deposited powder on the pads. Only a small quantity of solder powder adjacent to the pads can join the first step, so a quite uniform SoP array on the substrate can be easily obtained regardless of the pad configurations. Through this process, an SoP array on an organic substrate with a pitch of 130 μm is, successfully, formed.

Development of Lead-Free Flip Chip Package and Its Reliability

2003 ◽  
Author(s):  
Jeffrey C. B. Lee ◽  
Sting Wu ◽  
H. L. Chou ◽  
Yi-Shao Lai
Keyword(s):  
Failure Mode ◽  
Flip Chip ◽  
Failure Modes ◽  
Solder Bump ◽  
Wire Bonding ◽  
Point Of View ◽  
Lead Free ◽  
Temperature Cycle ◽  
Snagcu Solder ◽  
Temperature Cycle Test

SnAgCu solder used in laminate package like PBGA and CSP BGA to replace eutectic SnPb as interconnection has become major trend in the electronic industry. But unlike well-known failure mode of wire bonding package, flip chip package with SnAgCu inner solder bump and external solder ball as electrical interconnection present a extremely different failure mode with wire-bonding package from a point of view in material and process. In this study, one 16mm×16mm 3000 I/O SnAgCu wafer bumping using screen-printing process was explored including the effects of reflow times, high temperature storage life (HTSL) and temperature cycle test (TCT) on bump shear strength. Furthermore, the qualified wafer bumping is assembled by flip chip assembly with various underfill material and specific organic build-up substrate, then is subject to MSL4/260°C precondition and temperature cycle test to observe the underfill effect on SnAgCu bump protection and solder joint life. Various failure modes in the flip chip package like solder bump, underfill and UBM and so on, will be scrutinized with SEM. And finally, best material combination will be addressed to make the lead free flip package successful.

Experimental Study of Void Formation in Eutectic and Lead-Free Solder Bumps of Flip-Chip Assemblies

2005 ◽  
Vol 128 (3) ◽  
pp. 202-207 ◽  
Author(s):  
Daijiao Wang ◽  
Ronald L. Panton
Keyword(s):  
Experimental Study ◽  
Heat Flux ◽  
Flip Chip ◽  
Void Formation ◽  
Lead Free ◽  
Void Volume ◽  
Lead Free Solder ◽  
Solder Bumps ◽  
Free Solder ◽  
High Lead

This paper reports the experimental findings of void formation in eutectic and lead-free solder joints of flip-chip assemblies. A previous theory indicated that the formation of voids is determined by the direction of heating. The experiments were designed to examine the size and location of voids in the solder samples subject to different heat flux directions. A lead-free solder (Sn-3.5Ag-0.75Cu) and a eutectic solder (63Sn37Pb) were employed in the experiments. Previous experiments [Wang, D., and Panton, R. L., 2005, “Experimental Study of Void Formation in High-Lead Solder Joints of Flip-Chip Assemblies,” ASME J. Electron. Packag., 127(2), pp. 120–126; 2005, “Effect of Reversing Heat Flux Direction During Reflow on Void Formation in High-Lead Solder Bumps,” ASME J. Electron. Packag., 127(4), pp. 440–445] employed a high lead solder. 288 solder bumps were processed for each solder. Both eutectic and lead-free solder have shown fewer voids and much smaller void volume than those for high-lead solder. Compared with lead-free solder, eutectic solder has a slightly lower void volume and a lower percentage of defective bumps. For both eutectic and lead-free solders, irrespective of the cooling direction, heating solder samples from the top shows fewer defective bumps and smaller void volume. No significant effect on void formation for either eutectic or lead-free solder was found via reversing the heat flux direction during cooling. Unlike high-lead solder, small voids in eutectic or lead-free solder comprised 35-88% of the total void volume. The final distribution of voids shows a moderate agreement with thermocapillary theory, indicating the significance of the temperature gradient on the formation of voids.

Sign in / Sign up

Export Citation Format

Share Document