Cold Sprayed Copper-Diamond Composites for Thermal Management of Semiconductor Packages
Thermal management is key to enabling increasingly powerful chips and heterogeneous integrated 2.5D/3-D systems. Composite materials with high thermal conductivities that can be placed at different levels of proximity to the die provide new solutions for heat dissipation. Here we report the fabricat...
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Veröffentlicht in: | Journal of microelectronics and electronic packaging 2024-09, Vol.21 (3) |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | Thermal management is key to enabling increasingly
powerful chips and heterogeneous integrated 2.5D/3-D systems.
Composite materials with high thermal conductivities that can be
placed at different levels of proximity to the die provide new solutions
for heat dissipation. Here we report the fabrication of thick
copper-diamond composite films using cold spray, which is a
high-throughput, low-thermal-budget deposition technology. In
cold spray, feedstock micro powder is accelerated in a specially
designed nozzle by a heated pressurized gas and adheres to the
substrate upon high-speed impingement. This process achieves
higher deposition rates than other methods used in semiconductor
manufacturing (such as electroplating). It also produces films that
are denser and much less porous than ones produced by conventional
thermal spray techniques. In this work, we first use process
and thermal simulations to determine the requirements of the
micro diamond powder feedstock, including the diamond core
size, metal-clad thickness, core-clad interfacial resistance, and
volume fraction to enable the cold spray of copper-diamond composites
with thermal conductivities that are higher than copper.
Subsequently, we perform a systematic characterization of the
diamond powders from several suppliers, including the purity,
metal oxygen content, particle morphology, and metal-clad adhesion.
This characterization reveals the challenges of meeting all
the specs using currently available diamond powders. Finally, we
cold spray copper-diamond composite films on a variety of substrates
with tunable thicknesses between 100 mm and 2 mm,
achieving a thermal conductivity that is approximately 10%
higher than cold-sprayed pure copper. Further improvement of
the thermal properties relies on continued innovation in powder
surface modification and powder storage/shipping methods. |
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ISSN: | 1551-4897 1551-4897 |
DOI: | 10.4071/001c.124091 |