Manufacturing processes for fabrication of flip-chip micro-bumps used in microelectronic packaging: An overview

2019 ◽  
Vol 3 (1) ◽  
pp. 69-83 ◽  
Author(s):  
Madhav Datta
Keyword(s):  
Electronic Packaging ◽  
High Performance ◽  
Flip Chip ◽  
Semiconductor Industry ◽  
Void Formation ◽  
High Volume ◽  
Lead Free ◽  
Manufacturing Processes ◽  
Solder Paste ◽  
Chip Technology

Electronic packaging is the methodology for connecting and interfacing the chip technology with a system and the physical world. The objective of packaging is to ensure that the devices and interconnections are packaged efficiently and reliably. Chip–package interconnection technologies currently used in the semiconductor industry include wire bonding, tape automated bonding and flip-chip solder bump connection. Among these interconnection techniques, the flip-chip bumping technology is commonly used in advanced electronic packages since this interconnection is an area array configuration so that the entire surface of the chip can be covered with bumps for the highest possible input/output (I/O) counts. The present article reviews the manufacturing processes for the fabrication of flip-chip bumps for chip–package interconnection. Various solder bumping technologies used in high-volume production include evaporation, solder paste screening and electroplating. Evaporation process produces highly reliable bumps, but it is extremely expensive and is limited to lead or lead-rich solders. Solder paste screening is cost-effective, but issues related to excessive void formation limits the process to low-end products. On the other hand, electrochemical fabrication of flip-chip bumps is an extremely selective and efficient process, which is extendible to finer pitch, larger wafers and a variety of solder compositions, including lead-free alloys. Electrochemically fabricated copper pillar bumps offer fine pitch capabilities with excellent electromigration performance. Due to these virtues, the copper pillar bumping technology is emerging as a lead-free bumping technology option for high-performance electronic packaging.

Bumping Process Impact on the Chip Package Interaction (CPI) Reliability

2018 ◽  
Vol 2018 (1) ◽  
pp. 000270-000276 ◽  
Author(s):  
Lei Fu ◽  
Milind Bhagavat ◽  
Ivor Barber
Keyword(s):  
Integrated Circuit ◽  
Seed Layer ◽  
High Performance ◽  
Flip Chip ◽  
Leading Edge ◽  
Lead Free ◽  
Assembly Process ◽  
Chip Technology ◽  
Layer Deposition ◽  
Ic Package

Abstract Flip chip technology is widely used in advanced integrated circuit (IC) package. Chip package interaction (CPI) became critical in flip chip technology that needed to be addressed to avoid electrical or mechanical failure in products. When addressing CPI challenges, different areas have to be considered, ranging from silicon BEOL design and processing, bumping design and process, package assembly process, assembly bill of material (BOM), and substrate technology. Controlled collapse chip connection (C4) bump technology provided the inter-connection between the IC to package substrate for high-performance, leading-edge microprocessors. It is very critical for chip package interaction (CPI). With the transfer to lead free technology, bumping process plays more and more important role for chip package interaction reliability. In this paper, we focused on bumping process effect on the CPI reliability. The bumping process has been reviewed and CPI reliability issues induced by the bumping process like particles, Ti seed layer deposition, UBM undercut, Cu pad oxidation and contamination, photoresist opening damage have been discussed. Bumping process optimization and corrective actions have been taken to reduce those defects and improve CPI reliability.

3D Integration of System-in-Package (SiP): Toward SiP-Interposer-SiP for High-End Electronics

2013 ◽  
Vol 2013 (DPC) ◽  
pp. 000618-000634 ◽  
Author(s):  
Rabindra Das ◽  
Frank D. Egitto ◽  
Steven G. Rosser ◽  
Erich Kopp ◽  
Barry Bonitz
Keyword(s):  
High Performance ◽  
Flip Chip ◽  
Integrated Approach ◽  
Solder Paste ◽  
Printed Wiring Board ◽  
3D Integration ◽  
Passive Components ◽  
Chip Technology ◽  
Small Pitch ◽  
Electrically Conductive Adhesive

The demand for high-performance, lightweight, portable computing power is driving the industry toward 3D integration to meet the demands of higher functionality in ever smaller packages. To accomplish this, new packaging needs to be able to integrate multiple substrates, multiple dies with greater function, higher I/O counts, smaller pitches, and greater heat densities, while being pushed into smaller and smaller footprints. The approaches explored in this paper include eliminating active chip packages by directly attaching the chip to the System-in-Package (SiP) with flip chip technology. Additionally, the area devoted to passive components can be greatly reduced by embedding many of the capacitors and resistors. In some instances, the connector systems that were consuming large amounts of space in the traditional Printed Wiring Board (PWB) assembly can be reduced with a small pitch connector system. This PWB assembly can then be transformed into a much smaller SiP with the full surface area on both sides of the package effectively utilized by active and passive components. The miniaturized SiP with its reduced package size and demand for passives requires a high wireability package with embedded passives and excellent communication from top to bottom. In the present study, we also report novel 3D “Package Interposer Package” (PIP) solution for combining multiple SiP substrates into a single package. A variety of interposer structures were used to fabricate SiP-Interposer-SiP modules. Electrical connections were formed during reflow using a tin-lead eutectic solder paste. Interconnection among substrates (packages) in the stack was achieved using interposers. Plated through holes in the interposers, formed by laser or mechanical drilling and having diameters ranging from 50 m to 250 m, were filled with an electrically conductive adhesive and cured. The adhesive-filled and cured interposers were reflowed with circuitized substrates to produce a PIP structure. In summary, the present work describes an integrated approach to develop 3D PIP solutions on various SiP configurations.

3D Integration of System-in-Package (SiP) Using Organic Interposer: Toward SiP-Interposer-SiP for High-End Electronics

2013 ◽  
Vol 2013 (1) ◽  
pp. 000531-000537 ◽  
Author(s):  
Rabindra N. Das ◽  
Frank D. Egitto ◽  
Steven G. Rosser ◽  
Erich Kopp ◽  
Barry Bonitz ◽  
...  
Keyword(s):  
High Performance ◽  
Flip Chip ◽  
Integrated Approach ◽  
Solder Paste ◽  
Printed Wiring Board ◽  
3D Integration ◽  
Passive Components ◽  
Chip Technology ◽  
Small Pitch ◽  
Electrically Conductive Adhesive

The demand for high-performance, lightweight, portable computing power is driving the industry toward 3D integration to meet the demands of higher functionality in ever smaller packages. To accomplish this, new packaging needs to be able to integrate multiple substrates, multiple dies with greater function, higher I/O counts, smaller pitches, and greater heat densities, while being pushed into smaller and smaller footprints. The approaches explored in this paper include eliminating active chip packages by directly attaching the chip to the System-in-Package (SiP) with flip chip technology. Additionally, the area devoted to passive components can be greatly reduced by embedding many of the capacitors and resistors. In some instances, the connector systems that were consuming large amounts of space in the traditional Printed Wiring Board (PWB) assembly can be reduced with a small pitch connector system. This PWB assembly can then be transformed into a much smaller SiP with the full surface area on both sides of the package effectively utilized by active and passive components. The miniaturized SiP with its reduced package size and embedded passives provides a high wireability package with excellent communication from top to bottom. In the present study, we also report a novel 3D “Package-Interposer-Package” (PIP) solution for combining multiple SiP substrates into a single package. A variety of interposer structures were used to fabricate SiP-Interposer-SiP modules. Electrical connections were formed during reflow using a tin-lead eutectic solder paste. Interconnection among substrates (packages) in the stack was achieved using interposers. Plated through holes in the interposers, formed by laser or mechanical drilling and having diameters ranging from 50 μm to 250 μm, were filled with an electrically conductive adhesive and cured. The adhesive-filled and cured interposers were reflowed with circuitized substrates to produce a PIP structure. In summary, the present work describes an integrated approach to develop 3D PIP solutions incorporating various SiP configurations.

Thin-Die Flip Chip Physical-FA Process Flow

2002 ◽  
Author(s):  
Andrew J. Komrowski ◽  
N. S. Somcio ◽  
Daniel J. D. Sullivan ◽  
Charles R. Silvis ◽  
Luis Curiel ◽  
...  
Keyword(s):  
Sample Preparation ◽  
Failure Analysis ◽  
Flip Chip ◽  
Semiconductor Industry ◽  
Organic Substrate ◽  
Fault Isolation ◽  
Preparation Methods ◽  
Chip Technology ◽  
Isolation Test ◽  
Sample Preparation Methods

Abstract The use of flip chip technology inside component packaging, so called flip chip in package (FCIP), is an increasingly common package type in the semiconductor industry because of high pin-counts, performance and reliability. Sample preparation methods and flows which enable physical failure analysis (PFA) of FCIP are thus in demand to characterize defects in die with these package types. As interconnect metallization schemes become more dense and complex, access to the backside silicon of a functional device also becomes important for fault isolation test purposes. To address these requirements, a detailed PFA flow is described which chronicles the sample preparation methods necessary to isolate a physical defect in the die of an organic-substrate FCIP.

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.

Understanding Mold Compound Behavior on Flip Chip QFN Packages

2018 ◽  
Vol 2018 (1) ◽  
pp. 000125-000128
Author(s):  
Ruby Ann M. Camenforte ◽  
Jason Colte ◽  
Richard Sumalinog ◽  
Sylvester Sanchez ◽  
Jaimal Williamson
Keyword(s):  
Thermal Performance ◽  
High Performance ◽  
Flip Chip ◽  
Low Cost ◽  
Semiconductor Industry ◽  
Gelation Time ◽  
Molding Process ◽  
Design Quality ◽  
Low Resistance ◽  
Die Attach

Abstract Overmolded Flip Chip Quad Flat No-lead (FCQFN) is a low cost flip chip on leadframe package where there is no need for underfill, and is compatible with Pb free or high Pb metallurgy. A robust leadframe design, quality solder joint formation and an excellent molding process are three factors needed to assemble a high performance FCQFN. It combines the best of both wirebonded QFN and wafer chip scale devices. For example, wafer chip scale has low resistance, but inadequate thermal performance (due to absence of thermal pad), whereas wirebonded QFN has good thermal performance (i.e., heat dissipated through conductive die attach material, through the pad and to the board) but higher resistance. Flip chip QFN combines both positive aspects – that is: low resistance and good thermals. One of the common defects for molded packages across the semiconductor industry is the occurrence of mold voiding as this can potentially affect the performance of a device. This paper will discuss how mold voiding is mitigated by understanding the mold compound behavior on flip chip QFN packages. Taking for example the turbulent mold flow observed on flip chip QFN causing mold voids. Mold compound material itself has a great contribution to mold voids, hence defining the correct attributes of the mold compound is critical. Altering the mold compound property to decrease the mold compound rheology is a key factor. This dynamic interaction between mold compound and flip chip QFN package configuration is the basis for a series of design of experiments using a full factorial matrix. Key investigation points are establishing balance in mold compound chemistry allowing flow between bump pitch, as well as the mold compound rheology, where gelation time has to be properly computed to allow flow across the leadframe. Understanding the flow-ability of mold compound for FCQFN, the speed of flow was optimized to check on its impact on mold voids. Mold airflow optimization is also needed to help fill in tighter bump spacing but vacuum-on time needs to be optimized as well.

Development of 3D System-in-Package with TSV Technology

2014 ◽  
Vol 2014 (1) ◽  
pp. 000612-000617 ◽  
Author(s):  
Shota Miki ◽  
Takaharu Yamano ◽  
Sumihiro Ichikawa ◽  
Masaki Sanada ◽  
Masato Tanaka
Keyword(s):  
High Performance ◽  
Flip Chip ◽  
Organic Substrate ◽  
Back Side ◽  
Final Thickness ◽  
Chip Technology ◽  
Type Semiconductor ◽  
Interconnect Reliability ◽  
Solder Balls ◽  
Carrier Wafer

In recent years, products such as smart phones, tablets, and wearable devices, are becoming miniaturized and high performance. 3D-type semiconductor structures are advancing as the demand for high-density assembly increases. We studied a fabrication process using a SoC die and a memory die for 3D-SiP (System in Package) with TSV technology. Our fabrication is comprised of two processes. One is called MEOL (Middle End of Line) for exposing and completing the TSV's in the SoC die, and the other is assembling the SoC and memory dice in a 3D stack. The TSV completion in MEOL was achieved by SoC wafer back-side processing. Because its final thickness will be a thin 50μm (typical), the SoC wafer (300 mm diameter) is temporarily attached face-down onto a carrier-wafer. Careful back-side grinding reveals the “blind vias” and fully opens them into TSV's. A passivation layer is then grown on the back of the wafer. With planarization techniques, the via metal is accessed and TSV pads are built by electro-less plating without photolithography. After the carrier-wafer is de-bonded, the thin wafer is sawed into dice. For assembling the 3D die stack, flip-chip technology by thermo-compression bonding was the method chosen. First, the SoC die with copper pillar bumps is assembled to the conventional organic substrate. Next the micro-bumps on the memory die are bonded to the TSV pads of the SoC die. Finally, the finished assembly is encapsulated and solder balls (BGA) are attached. The 3D-SiP has passed both package-level reliability and board-level reliability testing. These results show we achieved fabricating a 3D-SiP with high interconnect reliability.

Practical Application and Analysis of Lead-Free Solder on Chip-On-Flip-Chip SiP for Hearing Aids

2017 ◽  
Vol 2017 (1) ◽  
pp. 000201-000207 ◽  
Author(s):  
Youngtak Lee ◽  
Doug Link
Keyword(s):  
Hearing Aids ◽  
Flip Chip ◽  
Failure Modes ◽  
Lead Free ◽  
Lead Free Solder ◽  
Solder Paste ◽  
Practical Application ◽  
Surface Mount ◽  
Free Solder ◽  
On Chip

Abstract Due to rapid growth of the microelectronics industry, packaged devices with small form factors, low costs, high power performance, and increased efficiency have become of high demand in the market. To realize the current market development trend, flip chip interconnection and System-in-Package (SiP) are some of the promising packaging solutions developed. However, a surprising amount of surface mount technology (SMT) defects are associated with the use of lead-free solder paste and methods by which the paste is applied. Two such defects are solder extrusion and tombstoning. Considerable amount of defects associated with solder overflow are found on chip-on-flip-chip (COFC) SiP in hearing aids. Through the use of design of experiments (DOE), lead-free solder defect causes on hearing aids application can be better understood and subsequently reduced or eliminated. This paper will examine the failure modes of solder extrusion and tombstoning that occurred when two different types of lead-free solders, Sn-Ag-Cu (SAC) and BiAgX were used within a SiP for attachment of surface mount devices (SMD) chip components for hearing aid applications. The practical application and analysis of lead-free solder for hearing aids will include the comprehensive failure analysis of the SMD components and compare the modeling and analysis of the two different solder types through the DOE process.

C4 EM and CPI Reliability Benefits and Process Challenges of FBEOL Integration Changes Implemented in Lead-free C4 Products

2015 ◽  
Vol 2015 (1) ◽  
pp. 000787-000792
Author(s):  
E. Misra ◽  
T. Wassick ◽  
I. Melville ◽  
K. Tunga ◽  
D. Questad ◽  
...  
Keyword(s):  
Integrated Circuits ◽  
Flip Chip ◽  
Process Integration ◽  
Semiconductor Industry ◽  
Lead Free ◽  
Solder Interconnects ◽  
Design Changes ◽  
Modeling Data ◽  
Free Solder ◽  
Low K

The introduction of low-k & ultra-low-k dielectrics, lead-free (Pb-free) solder interconnects or C4's, and organic flip-chip laminates for integrated circuits have led to some major reliability challenges for the semiconductor industry. These include C4 electromigration (EM) and mechanical failures induced with-in the Si chip due to chip-package interactions (CPI). In 32nm technology, certain novel design changes were evaluated in the last Cu wiring level and the Far Back End of Line levels (FBEOL) to strategically re-distribute the current more uniformly through the Pb-free C4 bumps and therefore improve the C4 EM capabilities of the technology. FBEOL process integration changes, such as increasing the thickness of the hard dielectric (SiNx & SiOx) and reducing the final via diameter, were also evaluated for reducing the mechanical stresses in the weaker BEOL levels and mitigating potential risks for mechanical failures within the Si chip. The supporting white-bump, C4 EM and electrical/mechanical modeling data that demonstrates the benefits of the design and integration changes will be discussed in detail in the paper. Some of the key processing and integration challenges observed due to the design and process updates and the corresponding mitigation steps taken will also be discussed.

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.

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