Wafer Level Assembly Technique Development for Fine Pitch Flip Chip 3D Die-to-Wafer Integration

2010 ◽  
Vol 2010 (1) ◽  
pp. 000548-000553
Author(s):  
Zhaozhi Li ◽  
Brian J. Lewis ◽  
Paul N. Houston ◽  
Daniel F. Baldwin ◽  
Eugene A. Stout ◽  
...  
Keyword(s):  
Flip Chip ◽  
Low Cost ◽  
Three Dimensional ◽  
Cost Effective ◽  
Market Demand ◽  
Wafer Level ◽  
Packaging Technology ◽  
Fine Pitch ◽  
3D Packaging ◽  
Assembly Technique

Three Dimensional (3D) Packaging has become an industry obsession as the market demand continues to grow toward higher packaging densities and smaller form factor. In the meanwhile, the 3D die-to-wafer (D2W) packaging structure is gaining popularity due to its high manufacturing throughput and low cost per package. In this paper, the development of the assembly process for a 3D die-to-wafer packaging technology, that leverages the wafer level assembly technique and flip chip process, is introduced. Research efforts were focused on the high-density flip chip wafer level assembly techniques, as well as the challenges, innovations and solutions associated with this type of 3D packaging technology. Processing challenges and innovations addressed include flip chip fluxing methods for very fine-pitch and small bump sizes; wafer level flip chip assembly program creation and yield improvements; and set up of the Pb-free reflow profile for the assembled wafer. 100% yield was achieved on the test vehicle wafer that has totally 1,876 flip chip dies assembled on it. This work has demonstrated that the flip chip 3D die-to-wafer packaging architecture can be processed with robust yield and high manufacturing throughput, and thus to be a cost effective, rapid time to market alternative to emerging 3D wafer level integration methodologies.

Assembly Process Development for Fine Pitch Flip Chip Silicon-to-Silicon 3D Wafer Level Integration with No Flow Underfill

2010 ◽  
Vol 7 (3) ◽  
pp. 146-151 ◽  
Author(s):  
Zhaozhi Li ◽  
Sangil Lee ◽  
Brian J. Lewis ◽  
Paul N. Houston ◽  
Daniel F. Baldwin ◽  
...  
Keyword(s):  
High Performance ◽  
Flip Chip ◽  
Process Development ◽  
Low Cost ◽  
Three Dimensional ◽  
Process Time ◽  
Wafer Level ◽  
Fine Pitch ◽  
3D Packaging ◽  
Small Form Factor

The industry has witnessed the adoption of the flip chip for its low cost, small form factor, high performance, and great I/O flexibility. As three-dimensional (3D) packaging technology moves to the forefront, the flip chip to wafer integration, which is also a silicon-to-silicon assembly, is gaining more and more popularity. No flow underfill is of special interest for the wafer level flip chip assembly, as it can dramatically reduce the process time and the cost per package, due to the reduction in the number of process steps as well as the dispenser and cure oven that would otherwise be necessary for the standard capillary underfill process. This paper introduces the development of a no flow underfill process for a sub-100 micron pitch flip chip to CSP wafer level assembly. Challenges addressed include the no flow underfill reflow profile study, underfill dispense amount study, chip floating control, underfill voiding reduction, and yield improvement. Also, different no flow underfill candidates were investigated to determine the best performing processing material.

No Flow Underfill Process Development for Fine Pitch Flip Chip Silicon to Silicon Wafer Level Integration

2010 ◽  
Vol 2010 (DPC) ◽  
pp. 000708-000735 ◽  
Author(s):  
Zhaozhi Li ◽  
John L. Evans ◽  
Paul N. Houston ◽  
Brian J. Lewis ◽  
Daniel F. Baldwin ◽  
...  
Keyword(s):  
High Performance ◽  
Flip Chip ◽  
Process Development ◽  
Low Cost ◽  
Three Dimensional ◽  
High Yield ◽  
Process Time ◽  
Assembly Process ◽  
Wafer Level ◽  
Fine Pitch

The industry has witnessed the adoption of flip chip for its low cost, small form factor, high performance and great I/O flexibility. As the Three Dimensional (3D) packaging technology moves to the forefront, the flip chip to wafer integration, which is also a silicon to silicon assembly, is gaining more and more popularity. Most flip chip packages require underfill to overcome the CTE mismatch between the die and substrate. Although the flip chip to wafer assembly is a silicon to silicon integration, the underfill is necessary to overcome the Z-axis thermal expansion as well as the mechanical impact stresses that occur during shipping and handling. No flow underfill is of special interest for the wafer level flip chip assembly as it can dramatically reduce the process time as well as bring down the average package cost since there is a reduction in the number of process steps and the dispenser and cure oven that would be necessary for the standard capillary underfill process. Chip floating and underfill outgassing are the most problematic issues that are associated with no flow underfill applications. The chip floating is normally associated with the size/thickness of the die and volume of the underfill dispensed. The outgassing of the no flow underfill is often induced by the reflow profile used to form the solder joint. In this paper, both issues will be addressed. A very thin, fine pitch flip chip and 2x2 Wafer Level CSP tiles are used to mimic the assembly process at the wafer level. A chip floating model will be developed in this application to understand the chip floating mechanism and define the optimal no flow underfill volume needed for the process. Different reflow profiles will be studied to reduce the underfill voiding as well as improve the processing yield. The no flow assembly process developed in this paper will help the industry understand better the chip floating and voiding issues regarding the no flow underfill applications. A stable, high yield, fine pitch flip chip no flow underfill assembly process that will be developed will be a very promising wafer level assembly technique in terms of reducing the assembly cost and improving the throughput.

Thin Film Packaging Reinforcement for Overmolded MEMS

2010 ◽  
Vol 2010 (DPC) ◽  
pp. 001095-001119
Author(s):  
Gillot Charlotte ◽  
Jean-Louis Pornin ◽  
Christophe Billard ◽  
Emannuelle Lagoute ◽  
Mihel Pellat ◽  
...  
Keyword(s):  
Thin Film ◽  
Flip Chip ◽  
Low Cost ◽  
Short Circuit ◽  
Cost Effective ◽  
Wafer Level ◽  
Silicon Area ◽  
Mechanical Constraints ◽  
Test Card ◽  
Manufacturing Technologies

Thin Film packaging (TFP) is now well known at CEA/LETI and mainly used as a protection for MEMS against degradation which can occur during back end processes: TFP is strong enough to endure the mechanical constraints due to grinding, handling and protects the device from water during the sawing step. Our TFP process is also compatible with under bump metallisation, balling and flip chip processes. The main advantages of our TFP is a very low lost of silicon area, a low cost process with 3 mask levels, and is performed on equipments commonly used in IC fab. In this paper we will speek about process improvement for a TFP overmolded. The thermo-mechanical constraints due to the standard overmolding step (100 bars and 200°C) are much more challenging for TFP: the cavity is about 5 μm high, the cap layer 2μm thick and the polymer plugging layer 6μm thick. So TFP needs to be reinforced to withstand these high constraints. Two processes using conventional IC manufacturing technologies have been developed at wafer level with two materials. 200μm and 500μm wide cavities with TFP were reinforced with these processes and first tested under pneumatically pressure at room temperature: in case of contact between the cap and the substrate, a short circuit is measured between one electrode on the substrate and another electrode behind the cap. Then, the same devices were overmolded at 75 bars and 100 bars at 185°C. In the same run, BAW resonators with TFP and one type of reinforcement were overmolded at 100 bars. The electrical performances of these resonators after overmolding fit very well to the modelling of the test card and are very good. This Compatibility between TFP and overmolding constraints could be a cost effective solution in MEMS packaging.

Advanced Substrate Applied Fluxing Underfill for Bonding of Fine Pitch Solder Capped Cu Pillars to Oxidized Cu Substrates

2012 ◽  
Vol 2012 (DPC) ◽  
pp. 000924-000943
Author(s):  
Russell Stapleton ◽  
Jim Greig
Keyword(s):  
Cross Sections ◽  
Flip Chip ◽  
Low Cost ◽  
Cost Effective ◽  
Filler Loading ◽  
Thermal Compression ◽  
Transparent Substrate ◽  
Fine Pitch ◽  
Before And After ◽  
Cu Substrates

Underfill solutions for fine pitch flip chip assemblies is an active area of development. Non-conductive films (NCF) and pastes (NCP) have shown great potential in bridging the gap between no-flow and capillary underfills for improving the reliability of fine pitched devices. But NCFs and NCPs require costly passivated pad finishes (e.g. Au, Sn, Ni, OSP) or careful substrate handling for proper solder joint formation. In this paper, we will describe a new class of underfill material that benefits from the growing trend of using thermal compression bonding as a cost effective alternative to mass reflow based underfilling processes (e.g. capillary and no-flow). This material is a fluxing NCP that is useful for a wide variety of fine pitch substrates, including low cost Cu. The material we will demonstrate contains many advanced features: high filler loading, strong flux activity, long work life, off-tool pre-dispense, low stress, high Tg, high modulus and rapid cure. The all-in-one underfill demonstrated in this paper is applied by using a screen printing process, where the material is applied to all of the chip sites in one step achieving excellent application efficiency and wetting/conformity to the substrate. The substrate is glass, containing a 4x4 array of die sites. Each of the die sites are 5x5mm in size with a full area array of 2501 Cu pads (50um pads on 100um pitch) that are pre-oxidized for 1h at 175C in air prior to printing (to simulate a dehydration bake). This transparent substrate was chosen to show the robust nature of the underfill for fluxing, stability and void-free placement/cure. Images of the substrate, before and after chip bonding will be given, along with cross sections. Details of the material properties will also be discussed.

Microbump Processing for 3D IC Integration

2019 ◽  
Vol 2019 (DPC) ◽  
pp. 001028-001049
Author(s):  
Feng Li ◽  
Andrew W. Owens ◽  
Qianyi Li
Keyword(s):  
Flip Chip ◽  
Low Cost ◽  
Three Dimensional ◽  
Bonding Process ◽  
Replication Process ◽  
Spatial Efficiency ◽  
Bonding Structure ◽  
Fine Pitch ◽  
Bonding Method ◽  
Self Replication

In recent years, the development of microbumps has allowed even smaller sizes of ICs to utilize the flip chip technique. In addition, microbumps have enabled the implementation of three-dimensional (3D) ICs, which drastically improve the spatial efficiency of packaging. However, as the bumps size decreases and the number increases, several process challenges must be considered, for example, the height consistency of bump, the ratio of miss and deformity bump and the yield and strength of interconnection, etc. Therefore, it is increasingly important to study the interconnection technology and materials of high-density microbump interconnection. After briefly introducing the common electronic packaging techniques, including wire bonding, tape-automated bonding and flip chip, this paper reviews microbumps as an advanced bonding technology. Techniques such as Controlled Collapse Chip Connection - New Process(C4NP), printing, insert bump bonding, and self-replication process are discussed and compared. C4NP can achieve low-cost, fine pitch bumping by utilizing varied lead-free solder alloys, which overcomes the limitation of existing bumping technologies. Depending on the microbump size, engraved mask stump, and photosensitive organic mask and squeegee are the two ways for micro-bump printing. The micro-insert bump bonding process is new to stack chips vertically, which has robust bonding structure and a simpler bonding process compared to Cu pillar bonding process. The self-replication process is using the surface tension property of molten solder between the micro bridged bump to get two bumps with same volume and geometries on each faced pairs of lands. The use of two common material for the microbump, Cu, Sn, and its alloys are presented along with the differences in the process for each. As with any technology, a new breakthrough addressing an issue brings with it its own set of shortfalls. Microbumps are no different. The various techniques and materials used to realize the reduced scale bonding method are subject to a number of challenges. Most prominent among them are electromigration, thermomigration, and thermallyinduced mechanical fatigue, which are discussed in this paper.

FOWLP Technology as an Wafer Level System in Packaging (SiP) Solution

2017 ◽  
Vol 2017 (DPC) ◽  
pp. 1-41 ◽  
Author(s):  
Lewis(In Soo) Kang
Keyword(s):  
High Performance ◽  
Flip Chip ◽  
Low Cost ◽  
Industrial Applications ◽  
System Control ◽  
Wafer Level ◽  
Communication Module ◽  
3D Packaging ◽  
Control Application ◽  
Wafer Level Package

The market of Connectivity, Internet of Things (IoT), Wearable and Smart industrial applications leads Fan Out Wafer Level Package (FOWLP) technologies to a promising solution to overcome the limitation of conventional wafer level package, flip chip package and wire bonding package in terms of the solution of low cost, high performance and smaller form factor packaging. Moreover, FOWLP technology can be extended to system-in-package (SiP) area, such as multi chip 2D package and 3D stack package types. nepes Corporation has developed several advanced package platforms such as single, multi dies and 2D, 3D packaging by using FOWLP and embedding technologies. To fulfill SiP (system-in-package) with FOWLP, several dies and components have been embedded into one package which offers 40~90 % of volumetric shrink compared to the current module system with the flexibility of product design for end users. 3D package technology of PoP (Package on Package) structure will be introduced for communication module and system control application.

scholarly journals Reliability Evaluation of Fan-Out Type 3D Packaging-On-Packaging

Micromachines ◽  
2021 ◽  
Vol 12 (3) ◽  
pp. 295
Author(s):  
Pao-Hsiung Wang ◽  
Yu-Wei Huang ◽  
Kuo-Ning Chiang
Keyword(s):  
Finite Element ◽  
Thermal Cycling ◽  
Glass Substrate ◽  
High Speed ◽  
Coefficient Of Thermal Expansion ◽  
Three Dimensional ◽  
Design Parameters ◽  
Time To Failure ◽  
Wafer Level ◽  
Fine Pitch

The development of fan-out packaging technology for fine-pitch and high-pin-count applications is a hot topic in semiconductor research. To reduce the package footprint and improve system performance, many applications have adopted packaging-on-packaging (PoP) architecture. Given its inherent characteristics, glass is a good material for high-speed transmission applications. Therefore, this study proposes a fan-out wafer-level packaging (FO-WLP) with glass substrate-type PoP. The reliability life of the proposed FO-WLP was evaluated under thermal cycling conditions through finite element simulations and empirical calculations. Considering the simulation processing time and consistency with the experimentally obtained mean time to failure (MTTF) of the packaging, both two- and three-dimensional finite element models were developed with appropriate mechanical theories, and were verified to have similar MTTFs. Next, the FO-WLP structure was optimized by simulating various design parameters. The coefficient of thermal expansion of the glass substrate exerted the strongest effect on the reliability life under thermal cycling loading. In addition, the upper and lower pad thicknesses and the buffer layer thickness significantly affected the reliability life of both the FO-WLP and the FO-WLP-type PoP.

Innovative 3D Structures Utilizing Wafer Level Fan-Out (WLFO) Technology

2013 ◽  
Vol 2013 (DPC) ◽  
pp. 001486-001519
Author(s):  
Curtis Zwenger ◽  
JinYoung Khim ◽  
YoonJoo Khim ◽  
SeWoong Cha ◽  
SeungJae Lee ◽  
...  
Keyword(s):  
Low Cost ◽  
Ease Of Use ◽  
Wafer Level ◽  
3D Structures ◽  
Wafer Level Packaging ◽  
Functional Convergence ◽  
3D Packaging ◽  
Improved Design ◽  
On Chip ◽  
Mobile Handset

The tremendous growth in the mobile handset, tablet, and networking markets has been fueled by consumer demand for increased mobility, functionality, and ease of use. This, in turn, has been driving an increase in functional convergence and 3D integration of IC devices, resulting in the need for more complex and sophisticated packaging techniques. A variety of advanced IC interconnect technologies are addressing this growing need, such as Thru Silicon Via (TSV), Chip-on Chip (CoC), and Package-on-Package (PoP). In particular, the emerging Wafer Level Fan-Out (WLFO) technology provides unique and innovative extensions into the 3D packaging realm. Wafer Level Fan-Out is a package technology designed to provide increased I/O density within a reduced footprint and profile for low density single & multi-die applications at a lower cost. The improved design capability of WLFO is due, in part, to the fine feature capabilities associated with wafer level packaging. This can allow much more aggressive design rules to be applied compared to competing laminate-based technologies. In addition, the unique characteristics of WLFO enable innovative 3D structures to be created that address the need for IC integration in emerging mobile and networking applications. This paper will review the development of WLFO and its extension into unique 3D structures. In addition, the advantages of these WLFO designs will be reviewed in comparison to current competing packaging technologies. Process & material characterization, design simulation, and reliability data will be presented to show how WLFO is poised to provide robust, reliable, and low cost 3D packaging solutions for advanced mobile and networking products.

Through Silicon Via Technology: Cost effective Cu-TSV Interconnects by EMC3D and Technical Challenges with Cu-TSV

2010 ◽  
Vol 2010 (DPC) ◽  
pp. 000425-000445
Author(s):  
Paul Siblerud ◽  
Rozalia Beica ◽  
Bioh Kim ◽  
Erik Young
Keyword(s):  
Low Cost ◽  
Cost Effective ◽  
High Yield ◽  
Integrated Process ◽  
Wafer Level ◽  
Through Silicon Via ◽  
Wafer Level Packaging ◽  
Current State ◽  
Future Technologies ◽  
Ic Technology

The development of IC technology is driven by the need to increase performance and functionality while reducing size, power and cost. The continuous pressure to meet those requirements has created innovative, small, cost-effective 3-D packaging technologies. 3-D packaging can offer significant advantages in performance, functionality and form factor for future technologies. Breakthrough in wafer level packaging using through silicon via technology has proven to be technologically beneficial. Integration of several key and challenging process steps with a high yield and low cost is key to the general adoption of the technology. This paper will outline the breakthroughs in cost associated with an iTSV or Via-Mid structure in a integrated process flow. Key process technologies enabling 3-D chip:Via formationInsulator, barrier and seed depositionCopper filling (plating),CMPWafer thinningDie to Wafer/chip alignment, bonding and dicing This presentation will investigate these techniques that require interdisciplinary coordination and integration that previously have not been practiced. We will review the current state of 3-D interconnects and the of a cost effective Via-first TSV integrated process.

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.

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