Characterization of nickel plated copper heat spreaders with different catalytic activation processes for flip-chip ball grid array package

Characterization of nickel plated copper heat spreaders with different catalytic activation processes for flip-chip ball grid array package

This paper presents the effects of two different catalytic activation techniques on the thermal performance of flip chip heat spreaders. The two activation techniques investigated are i) thin nickel-copper strike and ii) galvanic initiation. Thermal diffusivity of these heat spreaders was studied us...

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Bibliographic Details
Main Authors: Lim V., Ahmad I., Seng F.C., Amin N., Rasid R.
Other Authors: 26432767800
Format: Conference Paper
Published: 2023
Subjects:
Electronics packaging
Flip chip devices
Heating equipment
Mixed convection
Nickel
Nickel alloys
Soldering alloys
Spreaders
Thermal diffusion
Thermal diffusivity
Activation techniques
After high temperature
Catalytic activation
Copper heat spreader
Copper layer
Copper strike
Flip chip
Flip chip ball grid array
Heat spreaders
High temperature storage test
Initial time
Intermetallic diffusion
Intermetallic layer
Pure copper
Semiconductor packages
Thermal Performance
Copper
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Institution: Universiti Tenaga Nasional
Description
Summary:This paper presents the effects of two different catalytic activation techniques on the thermal performance of flip chip heat spreaders. The two activation techniques investigated are i) thin nickel-copper strike and ii) galvanic initiation. Thermal diffusivity of these heat spreaders was studied using the Nano-flash Apparatus [1]. High temperature storage tests were run to investigate the extent of intermetallic diffusion between the nickel and copper layers. The results obtained showed that heat spreaders processed with thin nickel-copper strike catalytic activation technique formed thick nickel-copper intermetallic layers compared to those processed with galvanic initiation. Nickel-copper intermetallic layers have lower thermal conductivity compared to pure copper [2]. As a result, heat spreaders processed with thin nickel copper strike have lower thermal diffusivity values averaged at 35-65W/mK XX compared to 60-85W/mK YY measured for those processed with galvanic-initiation. It is also discovered that the nickel-copper intermetallic layers of these heat spreaders grew thicker from 0.2?m at initial time until around 0.55?m after high temperature storage of 168 hours, further degrading the thermal diffusivity of these heat spreaders. As a conclusion, the galvanic initiation technique provides better thermal performance for heat spreaders used in semiconductor packages.

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