Publication: A practical investigation on nickel plated copper heat spreader with different catalytic activation processes for flip-chip ball grid array packages
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Date
2009
Authors
Amin N.
Lim V.
Seng F.C.
Razid R.
Ahmad I.
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Abstract
This study investigates the effects of two different catalytic activation techniques on the thermal performance of the flip-chip heat spreaders. The two activation techniques studied are thin nickel-copper strike and galvanic initiation. Thermal diffusivity and surface roughness of these heat spreaders were studied using the Nano-flash Apparatus and Infinite Focus Microscopy. High temperature storage tests were carried out to investigate the extent of intermetallic diffusion between the nickel and copper layers. The results show that heat spreaders with thin nickel-copper strike catalytic activation technique have a lower thermal diffusivity due to the low thermal conductivity of nickel-copper layer. Moreover, the nickel-copper layers grew thicker from around 0.2 ?m at initial time to around 0.55 ?m after high temperature storage duration of 168 h. On the other hand, heat spreaders processed using the galvanic initiation technique did not form any nickel-copper intermetallic diffusion layer. As a conclusion, the galvanic initiation technique can potentially provide better thermal performance for heat spreaders used in semiconductor packages. � 2009 Elsevier Ltd. All rights reserved.
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Keywords
Copper , Electric batteries , Electronics packaging , Flip chip devices , Heating equipment , Mixed convection , Nickel , Nickel alloys , Surface roughness , Thermal conductivity , Thermal diffusion , Activation techniques , After high temperatures , Catalytic activations , Copper heat spreaders , Copper layers , Copper strikes , Flip chips , Flip-chip ball grid arrays , Heat spreaders , High temperature storage tests , Initial time , Intermetallic diffusions , Low thermal conductivities , Practical investigations , Semiconductor packages , Thermal performance , Spreaders