DocumentCode
2586314
Title
Investigation of Carbon Nanotube Performance under External Mechanical Stresses and Moisture
Author
Fan, Haibo ; Zhang, Kai ; Yuen, Matthew M F
Author_Institution
Dept. of Mech. Eng., Hong Kong Univ. of Sci. & Technol., Hong Kong
fYear
2007
fDate
16-18 April 2007
Firstpage
1
Lastpage
4
Abstract
Due to its remarkable properties, carbon nanotube (CNT) was widely used in different areas, especially in electronic packaging for the improvement of the adhesion and thermal conductivity. CNT as an emerging thermal interface material (TIM) is now widely used to improve thermal dissipation in electronic packaging. CNTs suffer from moisture or high interfacial stresses from the mismatch of the thermal expansion coefficient between different layers in packages during fabrication and assembly. Both of these factors have an effect on the material performance of CNTs. To apply CNTs in electronic packaging, it is important for us to understand these loading effects on the thermal performance of CNTs at an atomic level. Molecular dynamics (MD) simulation is a proper method to study these material properties of CNTs. In this study MD simulations were conducted to investigate the thermal conduction of CNT under different conditions, including mechanical stresses and moisture. A series of MD models were built using the Materials studio software (Accelrys, Inc). Based on Fourier´s law, thermal conductivities of the SWCNT under different conditions were calculated. The MD simulation results showed that the thermal conductivity of SWCNT subjected to axial stress decreased with the stress changing from the compression to tension. Both of moisture and torsion stress degraded the intrinsic thermal conductivity of CNT. This MD simulation gave a basic understanding of the surrounding effect on thermal performance of CNTs and provided information for the assembly of CNT in electronic packaging.
Keywords
carbon nanotubes; compressive strength; cooling; electronics packaging; moisture; molecular dynamics method; thermal conductivity; torsion; C; Materials studio software; carbon nanotube; electronic packaging; external mechanical stresses; moisture; molecular dynamics simulation; thermal conductivity; thermal dissipation; thermal interface material; torsion stress; Adhesives; Assembly; Carbon nanotubes; Conducting materials; Electronic packaging thermal management; Electronics packaging; Moisture; Thermal conductivity; Thermal expansion; Thermal stresses;
fLanguage
English
Publisher
ieee
Conference_Titel
Thermal, Mechanical and Multi-Physics Simulation Experiments in Microelectronics and Micro-Systems, 2007. EuroSime 2007. International Conference on
Conference_Location
London
Print_ISBN
1-4244-1105-X
Electronic_ISBN
1-4244-1106-8
Type
conf
DOI
10.1109/ESIME.2007.360034
Filename
4201201
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