Flip chip

Flip chip, also known as Controlled Collapse Chip Connection or its acronym, C4, is a method for interconnecting semiconductor devices, such as IC chips and Microelectromechanical systems (MEMS), to external circuitry with solder bumps that have been deposited onto the chip pads. The solder bumps are deposited on the chip pads on the top side of the wafer during the final wafer processing step. In order to mount the chip to external circuitry (e.g., a circuit board or another chip or wafer), it is flipped over so that its top side faces down, and aligned so that its pads align with matching pads on the external circuit, and then the solder is flowed to complete the interconnect. This is in contrast to wire bonding, in which the chip is mounted upright and wires are used to interconnect the chip pads to external circuitry.

Contents 1 Process steps 2 Comparison of mounting technologies 2.1 Wire bonding/Thermosonic bonding 2.2 Flip chip 2.3 Advantages 2.4 Disadvantages 3 History 4 Alternatives 5 See also 6 References 7 Further reading 8 External links

[edit] Process steps

1. Integrated circuits are created on the wafer

2. Pads are metalized on the surface of the chips

3. Solder dots are deposited on each of the pads

4. Chips are cut

5. Chips are flipped and positioned so that the solder balls are facing the connectors on the external circuitry

6. Solder balls are then remelted (typically using hot air reflow)

7. Mounted chip is “underfilled” using an electrically-insulating adhesive

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[edit] Comparison of mounting technologies

[edit] Wire bonding/Thermosonic bonding

In typical semiconductor fabrication systems chips are built up in large numbers on a single large wafer of semiconductor material, typically silicon. The individual chips are patterned with small pads of metal near their edges that serve as the connections to an eventual mechanical carrier. The chips are then cut out of the wafer and attached to their carriers, typically via wire bonding such as Thermosonic Bonding. These wires eventually lead to pins on the outside of the carriers, which are attached to the rest of the circuitry making up the electronic system.

[edit] Flip chip

Processing a flip chip is similar to conventional IC fabrication, with a few additional steps.^[1] Near the end of the manufacturing process, the attachment pads are metalized to make them more receptive to solder. This typically consists of several treatments. A small dot of solder is then deposited on each metalized pad. The chips are then cut out of the wafer as normal.

Recently, high-speed mounting methods evolved through a cooperation between Reel Service Ltd. and Siemens AG in the development of a high speed mounting tape known as 'MicroTape.'[1]. By adding a tape-and-reel process into the assembly methodology, placement at high speed, typically 20,000 placements per hour are achievable using standard PCB assembly equipment.^{[citation needed]}

To attach the flip chip into a circuit, the chip is inverted to bring the solder dots down onto connectors on the underlying electronics or circuit board. The solder is then re-melted to produce an electrical connection, typically using an ultrasonic or alternatively reflow solder process. This also leaves a small space between the chip's circuitry and the underlying mounting. In most cases an electrically-insulating adhesive is then "underfilled" to provide a stronger mechanical connection, provide a heat bridge, and to ensure the solder joints are not stressed due to differential heating of the chip and the rest of the system.

[edit] Advantages

The resulting completed flip chip assembly is much smaller than a traditional carrier-based system; the chip sits directly on the circuit board, and is much smaller than the carrier both in area and height. The short wires greatly reduce inductance, allowing higher-speed signals, and also carry heat better.

[edit] Disadvantages

Flip chips have several disadvantages. The lack of a carrier means they are not suitable for easy replacement, or manual installation. They also require very flat surfaces to mount to, which is not always easy to arrange, or sometimes difficult to maintain as the boards heat and cool. Also, the short connections are very stiff, so the thermal expansion of the chip must be matched to the supporting board or the connections can crack.^[2] The underfill material acts as an intermediate between the difference in CTE of the chip and board.

[edit] History

The process was originally introduced commercially by IBM in the 1960s for individual transistors and diodes packaged for use in their mainframe systems.^[3] DEC followed IBM's lead, but was unable to achieve the quality they demanded, and eventually gave up on the concept. It was pursued once again in the mid-90s for the Alpha product line, but then abandoned due to the fragmentation of the company and subsequent sale to Compaq. In the 1970s it was taken up by Delco Electronics, and has since become very common in automotive applications.

[edit] Alternatives

Since the flip chip's introduction a number of alternatives to the solder bumps have been introduced, including gold balls or molded studs, electrically conductive polymer and the "plated bump" process that removes an insulating plating by chemical means. Flip chips have recently gained popularity among manufacturers of cell phones, pagers and other small electronics where the size savings are valuable.^{[citation needed]}

[edit] See also

• Solid Logic Technology
• IBM 3081

[edit] References

[edit] Further reading

• Wikihowto: Guide to IC packages
• “Challenges in the Assembly of Large Die, High Bump Density Pb-Free Flip Chip Packages”, J. Libres, K. Robinson , Int’l Electronics Manufacturing Technology Symposium 2007 p. 346
• “Thermal and Mechanical Behaviors of Underfills for Flip-Chip Packaging”, H. Wu, C. Poo, L. Waf, and W. Mee, Electronics Packaging Technology Conference 2005 p. 842
• “Flip Chip Processing Using Wafer-Applied Underfills”, S. Busch and D. Baldwin [Ga Tech], Electronic Components and Technology Conference 2005 p. 297
• “The effect of underfill imperfections on the reliability of flip chip modules: FEM simulations and experiments”, S. Rzepka, F. feustel, E. Meusel, M. Korhonen and C. Li, 1998 Electronic Components and Technology Conference p. 362
• “Manufacturing Multichip Modules”, p. 391ff, by Rakesh Agarwal and Michael Pecht, in Physical Architecture of VLSI Systems, ed. Robert J. Hannemann, Allan D. Kraus and Michael Pecht; John Wiley & Sons Inc., New York (1994)
• “Solderable Contacts for Flip Chip Integrated Circuit Devices”, William D. Higdon, Susan Mach, and Ralph Cornell, US Patent 5,547,740, Aug 20, 1996
• “Solder jet printing of micropads and vertical interconnects”, Wallace, D.B.; Hayes, D.J., SMTA National Symposium, Emerging Technologies. Proceeding of the Technical Program Edina, MN, USA: Surface Mount Technol. Assoc, 1997. p. 55-61 Conference: Bloomington, MN, USA, 20-23 Oct 1997
• “Advanced solder flip chip processes” , Rinne, G.; Koopman, N.; Magill, P.; Nangalia, S.; Berry, C.; Mis, D.; Rogers, V.; Adema, G.; Berry, M.; Deane, P. SMI. Surface Mount International. Advanced Electronics Manufacturing Technologies. Proceedings of The Technical Program Edina, MN, USA: Surface Mount Technol. Assoc, 1996. p. 282-92 vol.1 of 2 vol. 826 pp. Conference: San Jose, CA, USA, 10-12 Sept 1996
• “Solder Bump Transfer Device for Flip Chip Integrated Circuit Devices”, Shing Yeh, William Higdon, Ralph Cornell, US Patent 5,607,099 Mar 4, 1997
• “Process for Converting a Wire Bond Pad to a Flip Chip Solder Bump Pad and Pad Formed Thereby”, Curt Erickson, US Patent 5,891,756 April 6, 1999
• “Process for Manufacturing a Multilayer Bumped Semiconductor Device”, Kamaran Manteghi, US Patent 5,863,812 Jan 26, 1999
• “Method of forming solder bumps”, Toshiharu Yanagida , US Patent 5,866,475; Feb. 2, 1999
• “Flip-chip packaging for smart MEMS” , Mayer, F.; Ofner, G.; Koll, A.; Paul, O.; Baltes, H., Proceedings of the SPIE (1998) vol.3328, p. 183-93. Conference: Smart Structures and Materials 1998: Smart Electronics and MEMS. San Diego, CA, USA, 2-4 March 1998
• “Wafer bumping technologies. A comparative analysis of solder deposition processes and assembly considerations”, Patterson, D.S.; Elenius, P.; Leal, J.A., Advances in Electronic Packaging 1997. Proceedings of the Pacific Rim/ASME International Intersociety Electronic and Photonic Packaging Conference. INTERpack ASME, 1997. p. 337-51 vol.1Conference: Kohala Coast, HI, USA, 15-19 June 1997
• “Solder Flip Chips Employing Electroless Nickel: An Evaluation of Reliability and Cost”, F. Stepniak , Advances in Electronic Packaging 1997 p. 353 (EEP Vol 19-1), ASME 1997
• “Zincation characterization for electroless Ni/Au UBM of solder bumping technology”, Tan, Q.; Beddingfield, C.; Mistry, A.; Mathew, V., Twenty Third IEEE/CPMT International Electronics Manufacturing Technology Symposium,New York, NY, USA: IEEE, 1998. p. 34; Conference: Austin, TX, USA, 19-21 Oct 1998
• “Solder bumping methods for flip chip packaging”, Rinne, G.A., 1997 Proceedings. 47th Electronic Components and Technology Conference IEEE, 1997. p. 240 Conference: San Jose, CA, USA, 18-21 May 1997
• “Flip-chip packaging with micromachined conductive polymer bumps”, Oh, K.W.; Ahn, C.H. , Proceedings of 3rd International Conference on Adhesive Joining and Coating Technology in Electronics Manufacturing 1998, p. 224 Conference: Binghamton, NY, USA, 28-30 Sept 1998
• “Low cost solder flip chip”, Rinne, G.A.; Magill, P.A. , Proceedings. 3rd International Symposium on Advanced Packaging Materials Processes, Properties and Interfaces 1997. p. 113 Conference: Braselton, GA, USA, 9-12 March 1997
• “Flip-chip packaging using micromachined conductive polymer bumps and alignment pedestals for MOEMS”, Oh, K.W.; Ahn, C.H.; Roenker, K.P., IEEE Journal of Selected Topics in Quantum Electronics (Jan.-Feb. 1999) vol.5, no.1, p. 119

[edit] External links

• Flip chip bonding
• Flip chip assembly videos
• Flip chip tutorials
• Flip Chip Assembly
• Flip Chip (C4) Benefits
• Kyocera America, Inc. - White Paper: Flip Chip Challenges
• An Innovative Approach for Breakthrough Reduction in Flip Chip Package Cost - White Paper
• A case for the application of MicroTape
• Pushing the barriers of wafer level device integration to higher assembly speed
• Molded Flip Chip - FCmBGA White Paper
• Molded Underfill (MUF) Technology for Flip Chip Packages in Mobile Applications - White Paper
• "Factors Affecting Electromigration and Current Carrying Capacity of Flip Chip and 3D IC Interconnects", White Paper
• "Flip Chip Bump Electromigration Reliability A comparison of Cu Pillar, High Pb, SnAg and SnPb Bump Structures", White Paper
• "Study of Interconnection Process for Fine Pitch Flip Chip," White Paper
• "Field Use Environment for a FCBGA in a Laptop Computer Application", White Paper
• "Study of FCMBGA with Low CTE Core Substrate", White Paper
• "Molded Underfill Development for FlipStack", White Paper
• "Study of Interconnection Process for Fine Pitch Flip Chip", White Paper
• "Comparative Electromigration Performance of Pb Free Flip Chip Joints with Varying Board Surface Condition", White Paper
• Application Specific Flip Chip Packages: Considerations and Options in Using FCIP