DocumentCode
1130839
Title
Sea of Leads Compliant I/O Interconnect Process Integration for the Ultimate Enabling of Chips With Low-
Interlayer Dielectrics
Author
Bakir, Muhannad S. ; Dang, Bing ; Emery, Richard ; Vandentop, Gilroy ; Kohl, Paul A. ; Meindl, James D.
Author_Institution
Microelectron. Res. Center, Georgia Inst. of Technol., Atlanta, GA, USA
Volume
28
Issue
3
fYear
2005
Firstpage
488
Lastpage
494
Abstract
Sea of leads (SoL) process integration for the series of steps required to transform a fully intact die at the wafer level to a die that is assembled onto a board is described. The primary goal is to address the issues involved in reconciling the fabrication and assembly requirements of compliant leads, such as SoL, with those of standard semiconductor processes and chip assembly techniques. The effort is motivated in-part by the potential failure of the low-
interlayer dielectric in microprocessors as a result of high mechanical stresses due to the coefficient of thermal expansion (CTE) mismatch between the chip and the board. SoL, and other compliant interconnections, mitigate this problem by mechanically decoupling the chip and the board. While compliant leads offer advantages over C4 technology, there is much to consider during the series of steps needed to transform the fully intact dice at the wafer level to dice that are assembled onto the board. The use of an encapsulation film over the leads during wafer sawing is shown to be necessary for slippery leads and other free-standing compliant leads. The use of a suitable flux when the leads are finished with a nickel–oxide nonwettable layer is essential for a successful wafer-level solder reflow. Successful die assembly using thermocompression bonding is demonstrated using two different SoL dice with correspondingly different substrates. The resistance of a chain of 30 cascaded leads is 2.7
.
interlayer dielectric in microprocessors as a result of high mechanical stresses due to the coefficient of thermal expansion (CTE) mismatch between the chip and the board. SoL, and other compliant interconnections, mitigate this problem by mechanically decoupling the chip and the board. While compliant leads offer advantages over C4 technology, there is much to consider during the series of steps needed to transform the fully intact dice at the wafer level to dice that are assembled onto the board. The use of an encapsulation film over the leads during wafer sawing is shown to be necessary for slippery leads and other free-standing compliant leads. The use of a suitable flux when the leads are finished with a nickel–oxide nonwettable layer is essential for a successful wafer-level solder reflow. Successful die assembly using thermocompression bonding is demonstrated using two different SoL dice with correspondingly different substrates. The resistance of a chain of 30 cascaded leads is 2.7
.Keywords
chip-on-board packaging; dielectric materials; encapsulation; integrated circuit interconnections; lead; microassembling; reflow soldering; wafer bonding; 2.7 ohm; I/O interconnect process integration; Pb; chip assembly techniques; coefficient of thermal expansion; compliant interconnections; compliant leads; die assembly; encapsulation film; low-k interlayer dielectric; low-k interlayer dielectrics; mechanical stresses; nickel-oxide nonwettable layer; sea of leads process integration; slippery leads; standard semiconductor processes; thermo-compression bonding; wafer level integration; wafer sawing; wafer-level solder reflow; Assembly; Dielectrics; Encapsulation; Fabrication; Lead compounds; Microprocessors; Sawing; Thermal expansion; Thermal stresses; Wafer bonding; Compliant leads; input/output (I/O); interconnects; low-; packaging;
fLanguage
English
Journal_Title
Advanced Packaging, IEEE Transactions on
Publisher
ieee
ISSN
1521-3323
Type
jour
DOI
10.1109/TADVP.2005.848386
Filename
1492518
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