Wafer level underfill for area array Cu pillar flip chip packaging of ultra low-k chips on organic substrates

2012 ◽  
Author(s):  
Jae-Woong Nah ◽  
Michael Gaynes ◽  
Eric Perfecto ◽  
Claudius Feger
Keyword(s):  
Flip Chip ◽  
Organic Substrates ◽  
Wafer Level ◽  
Cu Pillar ◽  
Area Array ◽  
Flip Chip Packaging ◽  
Low K

Microstructure Observation of Electromigration Behavior in Peripheral C2 Flip Chip Interconnection with Solder Capped Cu Pillar Bump

2011 ◽  
Vol 2011 (1) ◽  
pp. 000828-000836
Author(s):  
Yasumitsu Orii ◽  
Kazushige Toriyama ◽  
Sayuri Kohara ◽  
Hirokazu Noma ◽  
Keishi Okamoto ◽  
...  
Keyword(s):  
Aging Process ◽  
Flip Chip ◽  
Fem Simulation ◽  
Organic Substrate ◽  
Organic Substrates ◽  
Cross Sectional ◽  
Pillar Height ◽  
Cu Pillar ◽  
Fine Pitch ◽  
Low K

The electromigration behavior of 80μm bump pitch C2 (Chip Connection) interconnection is studied and discussed. C2 is a peripheral ultra fine pitch flip chip interconnection technique with solder capped Cu pillar bumps formed on Al pads that are commonly used in wirebonding technique. It allows us an easy control of the space between dies and substrates simply by varying the Cu pillar height. Since the control of the collapse of the solder bumps is not necessary, the technology is called the “C2 (Chip Connection)”. C2 bumps are connected to OSP surface treated Cu substrate pads on an organic substrate by reflow with no-clean process, hence the C2 is a low cost ultra fine pitch flip chip interconnection technology. The reliability tests on the C2 interconnection including thermal cycle tests and thermal humidity bias tests have been performed previously. However the reliability against electromigration for such small flip chip interconnections is yet more to investigate. The electromigration tests were performed on 80μm bump pitch C2 flip chip interconnections. The interconnections with two different solder materials were tested: Sn-2.5Ag and Sn100%. The effect of Ni layers electroplated onto the Cu pillar bumps on electromigration phenomena is also studied. From the cross-sectional analyses of the C2 joints after the tests, it was found that the presence of intermetallic compound (IMC) layers reduces the atomic migration of Cu atoms into Sn solder. The analyses also showed that the Ni layers are effective in reducing the migration of Cu atoms into solder. In the C2 joints, the under bump metals (UBMs) are formed by sputtered Ti/Cu layers. The electro-plated Cu pillar height is 45μm and the solder height is 25μm for 80μm bump pitch. The die size is 7.3-mm-square and the organic substrate is 20-mm-square with a 4 layer-laminated prepreg with thickness of 310μm. The electromigration test conditions ranged from 7 to 10 kA/cm2 with temperature ranging from 125 to 170°C. Intermetallic compounds (IMCs) were formed prior to the test by aging process of 2,000hours at 150°C. We have studied the effect of IMC layers on electromigration induced phenomena in C2 flip chip interconnections on organic substrates. The study showed that the IMC layers in the C2 joints formed by aging process can act as barrier layers to prevent Cu atoms from diffusing into Sn solder. Our results showed potential for achieving electromigration resistant joints by IMC layer formation. The FEM simulation results show that the current densities in the Cu pillar and the solder decrease with increasing Cu pillar height. However an increase in Cu pillar height also leads to an increase in low-k stress. It is important to design the Cu pillar structure considering both the electromigration performance and the low-k stress reduction.

Cost Comparison of Fan-out Wafer Level Packaging and Flip Chip Packaging

2017 ◽  
Vol 2017 (DPC) ◽  
pp. 1-37 ◽  
Author(s):  
Amy Lujan
Keyword(s):  
Flip Chip ◽  
Cost Effective ◽  
Cost Comparison ◽  
Cost Modeling ◽  
Wafer Level ◽  
Design Features ◽  
Wafer Level Packaging ◽  
Flip Chip Packaging ◽  
The Right ◽  
The Cost

In recent years, there has been increased focus on fan-out wafer level packaging with the growing inclusion of a variety of fan-out wafer level packages in mobile products. While fan-out wafer level packaging may be the right solution for many designs, it is not always the lowest cost solution. The right packaging choice is the packaging technology that meets design requirements at the lowest cost. Flip chip packaging, a more mature technology, continues to be an alternative to fan-out wafer level packaging. It is important for many in the electronic packaging industry to be able to determine whether flip chip or fan-out wafer level packaging is the most cost-effective option. This paper will compare the cost of flip chip and fan-out wafer level packaging across a variety of designs. Additionally, the process flows for each technology will be introduced and the cost drivers highlighted. A variety of package sizes, die sizes, and design features will be covered by the cost comparison. Yield is a key component of cost and will also be considered in the analysis. Activity based cost modeling will be used for this analysis. With this type of cost modeling, a process flow is divided into a series of activities, and the total cost of each activity is accumulated. The cost of each activity is determined by analyzing the following attributes: time required, labor required, material required (consumable and permanent), capital required, and yield loss. The goal of this cost comparison is to determine which design features drive a design to be packaged more cost-effectively as a flip chip package, and which design features result in a lower cost fan-out wafer level package.

On the Origins, Status, and Future of Flip Chip & Wafer Level Packaging

2010 ◽  
Vol 2010 (1) ◽  
pp. 000325-000332 ◽  
Author(s):  
Alan Huffman ◽  
Philip Garrou
Keyword(s):  
Technological Change ◽  
Flip Chip ◽  
Emerging Technologies ◽  
Unit Area ◽  
Form Factors ◽  
Electrical Performance ◽  
Wafer Level ◽  
3D Integration ◽  
Wafer Level Packaging ◽  
Area Array

As IC scaling continues to shrink transistors, the increased number of circuits per chip requires more I/O per unit area (Rent's rule). High I/O count, the need for smaller form factors and the need for better electrical performance drove the technological change towards die being interconnected (assembled) by area array techniques. This review will examine this evolution from die wire bonded on lead frames to flip chip die in wafer level or area array packages and discuss emerging technologies such as copper pillar bumps, fan out packaging, integrated passives, and 3D integration..

A Heterogeneous Array of Off-Chip Interconnects for Optimum Mechanical and Electrical Performance

2007 ◽  
Vol 129 (4) ◽  
pp. 460-468 ◽  
Author(s):  
Karan Kacker ◽  
Thomas Sokol ◽  
Wansuk Yun ◽  
Madhavan Swaminathan ◽  
Suresh K. Sitaraman
Keyword(s):  
Flip Chip ◽  
Dielectric Material ◽  
Coefficient Of Thermal Expansion ◽  
Semiconductor Industry ◽  
Organic Substrate ◽  
Electrical Performance ◽  
Integrative Approach ◽  
Wafer Level ◽  
Target Values ◽  
Low K

Demand for off-chip bandwidth has continued to increase. It is projected by the Semiconductor Industry Association in their International Technology Roadmap for Semiconductors that by the year 2015, the chip-to-substrate area-array input-output interconnects will require a pitch of 80 μm. Compliant off-chip interconnects show great potential to address these needs. G-Helix is a lithography-based electroplated compliant interconnect that can be fabricated at the wafer level. G-Helix interconnects exhibit excellent compliance in all three orthogonal directions, and can accommodate the coefficient of thermal expansion (CTE) mismatch between the silicon die and the organic substrate without requiring an underfill. Also, these compliant interconnects are less likely to crack or delaminate the low-k dielectric material in current and future integrated circuits. The interconnects are potentially cost effective because they can be fabricated in batch at the wafer level and using conventional wafer fabrication infrastructure. In this paper, we present an integrative approach, which uses interconnects with varying compliance and thus varying electrical performance from the center to the edge of the die. Using such a varying geometry from the center to the edge of the die, the system performance can be tailored by balancing electrical requirements against thermomechanical reliability concerns. The test vehicle design to assess the reliability and electrical performance of the interconnects is also presented. Preliminary fabrication results for the integrative approach are presented and show the viability of the fabrication procedure. The results from reliability experiments of helix interconnects assembled on an organic substrate are also presented. Initial results from the thermal cycling experiments are promising. Results from mechanical characterization experiments are also presented and show that the out-of-plane compliance exceeds target values recommended by industry experts. Finally, through finite element analysis simulations, it is demonstrated that the die stresses induced by the compliant interconnects are an order of magnitude lower than the die stresses in flip chip on board (FCOB) assemblies, and hence the compliant interconnects are not likely to crack or delaminate low-k dielectric material.

Analysis of flip-chip packaging challenges on copper/low-k interconnects

2003 ◽  
Vol 3 (4) ◽  
pp. 111-118 ◽  
Author(s):  
L.L. Mercado ◽  
C. Goldberg ◽  
Shun-Meen Kuo ◽  
Tien-Yu Lee ◽  
S.K. Pozder
Keyword(s):  
Flip Chip ◽  
Flip Chip Packaging ◽  
Low K
Sign in / Sign up

Export Citation Format

Share Document