Abstract
Increasing power densities in high-power electronic packages require advanced heat dissipation from their respective thermal interface materials (TIMs). Modern TIMs does not accommodate both factors of thermal performance and mechanical compliance with increasing device power density. Vertically aligned carbon nanotubes (VACNT) are advantageous in that their intrinsic properties promote both high thermal conductivity while maintaining a mechanically flexible/compliant interface. Therefore, it is a promises approach to use of carbon nanotubes (CNTs), specialty VACNTs, to make a novel interface heat transfer material. However, the high thermal contact resistance between VACNTs and substrate(s) has been a big issue to limit its application. In this study, the effect of post-processing techniques such as plasma treatment and surface metallization of VACNT layer (directly grown on Cu substrate) on interfacial properties of CNTs with mating substrate were explored and the thermal properties were evaluated via Laser Flash testing system. Thermal test results demonstrated that modifying the surface of the VACNT layer is effective method to improve interfacial attachment between CNTs and mating substrate. Results indicated that, among different VACNT surface modification methods, the plasma treated VACNT layer surface promote the best thermal properties of VACNT-based metal nanocomposite (MNC) as TIM. Compared to the unmodified VACNT layer, in this study, the interphase thermal resistance of the Cu/VACNT/matched substrate sample made from the plasma treated VACNT layer was reduced approximately 80%.
Highlights
Long-term electronic device failures are often due to thermally induced stress/fatigue that shows up as interfacial delamination
In order to improve the interface connection between the carbon nanotubes (CNTs) and the matching substrate, this study focused on the surface modification of the vertically aligned CNT arrays (VACNT) array grown on the Cu foil substrate, followed by optimum CNT-surface solder filtration processing to form a VACNT-based metal nanocomposite (MNC) structure
The changes on VACNT layer surface morphology before and after treatment as well as the effect of treated time were monitored with SEM, and the results are shown in Figures 5 and 6
Summary
Long-term electronic device failures are often due to thermally induced stress/fatigue that shows up as interfacial delamination. It has been reported that taking full advantage of the positive influence of CNTs on the effective thermal conductivity of nanocomposites is a challenge due to difficulties in homogeneous distribution of nanotubes in the matrix phase and proper orientation/alignment for an optimum thermal path (Chu et al, 2010; Firkowska et al, 2011). To overcome this problem, significant attention has shifted to using vertically aligned CNT arrays (VACNT) as a promising TIM structure
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