Thermomechanical Reliability of Nickel Pillar Interconnections Replacing Flip-Chip Solder Without Underfill

Thermomechanical Reliability of Nickel Pillar Interconnections Replacing Flip-Chip Solder Without Underfill

Interconnect technologies between ICs and packages or boards have a significant impact on the IC performance and packaging density. Today, the interconnections are typically accomplished with either wire bonding or flip-chip solders. While both of these technologies are incremental, they also run in...

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Veröffentlicht in:IEEE transactions on electronics packaging manufacturing 2008-10, Vol.31 (4), p.341-354
Hauptverfasser: Aggarwal, A.O., Raj, P.M., Baik-Woo Lee, Myung Jin Yim, Iyer, M., Wong, C.P., Tummala, R.R.
Format: Artikel
Sprache:eng
Schlagworte:
Anisotropic conductive film (ACF)
Applied sciences
Assembly
Bonding
Conducting materials
Density
Design. Technologies. Operation analysis. Testing
Electronics
Exact sciences and technology
Fabrication
failure analysis
fine-pitch interconnects
Integrated circuit packaging
Integrated circuits
Interconnect
Interconnections
Mechanical factors
Microelectronic fabrication (materials and surfaces technology)
nano-structured interconnect
Nanocomposites
Nanomaterials
Nanostructure
Nanostructured materials
Nickel
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
solder
Solders
Studies
Testing, measurement, noise and reliability
Thermomechanical processes
thermomechanical reliability
Wire
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container_end_page 354
container_issue 4
container_start_page 341
container_title IEEE transactions on electronics packaging manufacturing
container_volume 31
creator Aggarwal, A.O.
Raj, P.M.
Baik-Woo Lee
Myung Jin Yim
Iyer, M.
Wong, C.P.
Tummala, R.R.
description Interconnect technologies between ICs and packages or boards have a significant impact on the IC performance and packaging density. Today, the interconnections are typically accomplished with either wire bonding or flip-chip solders. While both of these technologies are incremental, they also run into either electrical or mechanical barriers as they are extended to higher density of interconnections. Downscaling traditional solder bump interconnect might not satisfy the thermomechanical reliability requirements at very fine-pitches. Alternate interconnection approaches such as compliant interconnects typically require lengthy connections and are therefore limited in terms of electrical properties, although expected to meet the mechanical requirements. This paper reports fine-pitch interconnection technologies using nano-structured nickel as primary interconnection material. The nano-grained nickels are produced by electroplating process. The primary nano-structured interconnects are assembled with different bonding methods to provide organic compatible low-temperature fabrication. Au-Sn and Sn-Cu are used for solder-based assembly of nano-nickel interconnections. Low modulus anisotropic conductive films (ACFs) are also used as an alternate bonding route of the solders. No underfilling is used in all the interconnect structures evaluated in this paper. Assembly are accomplished on different coefficient of thermal expansion (CTE) substrates including FR-4 with 18 ppm/degC, advanced organic substrates with 10 ppm/degC, novel low CTE (3 ppm/degC) substrates based on carbon-silicon carbide (C-SiC). The thermomechanical reliability of all the nano-interconnects assembled on different CTE substrates with different bonding approaches is evaluated by thermal shock testing and finite-element analysis. Nano-nickel interconnects bonded with the ACF showed the highest reliability withstanding 1500 cycles. In all cases, no apparent failure was observed in the primary nano-nickel metal interconnects. This technology is expected to be easily downscaled to submicrometer and nano-scale unlike the current solder technologies leading to true nano-interconnections.
doi_str_mv 10.1109/TEPM.2008.2001974
format Article
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Au-Sn and Sn-Cu are used for solder-based assembly of nano-nickel interconnections. Low modulus anisotropic conductive films (ACFs) are also used as an alternate bonding route of the solders. No underfilling is used in all the interconnect structures evaluated in this paper. Assembly are accomplished on different coefficient of thermal expansion (CTE) substrates including FR-4 with 18 ppm/degC, advanced organic substrates with 10 ppm/degC, novel low CTE (3 ppm/degC) substrates based on carbon-silicon carbide (C-SiC). The thermomechanical reliability of all the nano-interconnects assembled on different CTE substrates with different bonding approaches is evaluated by thermal shock testing and finite-element analysis. Nano-nickel interconnects bonded with the ACF showed the highest reliability withstanding 1500 cycles. In all cases, no apparent failure was observed in the primary nano-nickel metal interconnects. 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Au-Sn and Sn-Cu are used for solder-based assembly of nano-nickel interconnections. Low modulus anisotropic conductive films (ACFs) are also used as an alternate bonding route of the solders. No underfilling is used in all the interconnect structures evaluated in this paper. Assembly are accomplished on different coefficient of thermal expansion (CTE) substrates including FR-4 with 18 ppm/degC, advanced organic substrates with 10 ppm/degC, novel low CTE (3 ppm/degC) substrates based on carbon-silicon carbide (C-SiC). The thermomechanical reliability of all the nano-interconnects assembled on different CTE substrates with different bonding approaches is evaluated by thermal shock testing and finite-element analysis. Nano-nickel interconnects bonded with the ACF showed the highest reliability withstanding 1500 cycles. In all cases, no apparent failure was observed in the primary nano-nickel metal interconnects. 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Today, the interconnections are typically accomplished with either wire bonding or flip-chip solders. While both of these technologies are incremental, they also run into either electrical or mechanical barriers as they are extended to higher density of interconnections. Downscaling traditional solder bump interconnect might not satisfy the thermomechanical reliability requirements at very fine-pitches. Alternate interconnection approaches such as compliant interconnects typically require lengthy connections and are therefore limited in terms of electrical properties, although expected to meet the mechanical requirements. This paper reports fine-pitch interconnection technologies using nano-structured nickel as primary interconnection material. The nano-grained nickels are produced by electroplating process. The primary nano-structured interconnects are assembled with different bonding methods to provide organic compatible low-temperature fabrication. Au-Sn and Sn-Cu are used for solder-based assembly of nano-nickel interconnections. Low modulus anisotropic conductive films (ACFs) are also used as an alternate bonding route of the solders. No underfilling is used in all the interconnect structures evaluated in this paper. Assembly are accomplished on different coefficient of thermal expansion (CTE) substrates including FR-4 with 18 ppm/degC, advanced organic substrates with 10 ppm/degC, novel low CTE (3 ppm/degC) substrates based on carbon-silicon carbide (C-SiC). The thermomechanical reliability of all the nano-interconnects assembled on different CTE substrates with different bonding approaches is evaluated by thermal shock testing and finite-element analysis. Nano-nickel interconnects bonded with the ACF showed the highest reliability withstanding 1500 cycles. In all cases, no apparent failure was observed in the primary nano-nickel metal interconnects. This technology is expected to be easily downscaled to submicrometer and nano-scale unlike the current solder technologies leading to true nano-interconnections.</abstract><cop>New York, NY</cop><pub>IEEE</pub><doi>10.1109/TEPM.2008.2001974</doi><tpages>14</tpages></addata></record>
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subjects Anisotropic conductive film (ACF)
Applied sciences
Assembly
Bonding
Conducting materials
Density
Design. Technologies. Operation analysis. Testing
Electronics
Exact sciences and technology
Fabrication
failure analysis
fine-pitch interconnects
Integrated circuit packaging
Integrated circuits
Interconnect
Interconnections
Mechanical factors
Microelectronic fabrication (materials and surfaces technology)
nano-structured interconnect
Nanocomposites
Nanomaterials
Nanostructure
Nanostructured materials
Nickel
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
solder
Solders
Studies
Testing, measurement, noise and reliability
Thermomechanical processes
thermomechanical reliability
Wire
title Thermomechanical Reliability of Nickel Pillar Interconnections Replacing Flip-Chip Solder Without Underfill
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