TY - GEN
T1 - Enhancement of the thermal properties of a vertically aligned carbon nanotube thermal interface material using a tailored polymer
AU - Le Khanh, H.
AU - Divay, L.
AU - Ni, Y.
AU - Le Barny, P.
AU - Leveugle, E.
AU - Chastaing, E.
AU - Wyczisk, F.
AU - Ziaei, A.
AU - Volz, S.
AU - Bai, J.
PY - 2012
Y1 - 2012
N2 - This paper presents our results on thermal properties measurements of thermal interface materials based on vertically aligned carbon nanotubes. In this system, the total interface resistance is the sum of thermal resistances created by the contact between the growth surface and the CNTs, the intrinsic resistance of the CNTs array, and the contact between the loose end of the CNTs and the opposite substrate. The latter is reported to be the limiting factor in the optimization of the global interface resistance, and in this work, polymers are used to enhance the thermal contact. Two polymers are studied. It is shown that the use of a polymer as interface material, despite its low thermal conductivity, leads to an improvement of the total thermal resistance. Experimental data and equilibrium molecular dynamics (EMD) show that the thermal contact resistance when using a reactive polymer - able to establish covalent bonds with the CNTs - is at least three times lower than that with the Van der Waals interaction polymer. The reactive polymer also enhances adhesion between CNTs and the polymer, which allows the mechanical complete transfer of the aligned CNTs array from growth substrate to a copper substrate. This transfer process allows to expand applications for VACNTs.
AB - This paper presents our results on thermal properties measurements of thermal interface materials based on vertically aligned carbon nanotubes. In this system, the total interface resistance is the sum of thermal resistances created by the contact between the growth surface and the CNTs, the intrinsic resistance of the CNTs array, and the contact between the loose end of the CNTs and the opposite substrate. The latter is reported to be the limiting factor in the optimization of the global interface resistance, and in this work, polymers are used to enhance the thermal contact. Two polymers are studied. It is shown that the use of a polymer as interface material, despite its low thermal conductivity, leads to an improvement of the total thermal resistance. Experimental data and equilibrium molecular dynamics (EMD) show that the thermal contact resistance when using a reactive polymer - able to establish covalent bonds with the CNTs - is at least three times lower than that with the Van der Waals interaction polymer. The reactive polymer also enhances adhesion between CNTs and the polymer, which allows the mechanical complete transfer of the aligned CNTs array from growth substrate to a copper substrate. This transfer process allows to expand applications for VACNTs.
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M3 - Conference contribution
AN - SCOPUS:84872873712
SN - 9782355000225
T3 - 18th International Workshop on Thermal Investigation of ICs and Systems, THERMINIC 2012
SP - 221
EP - 224
BT - 18th International Workshop on Thermal Investigation of ICs and Systems, THERMINIC 2012
T2 - 18th International Workshop on Thermal Investigation of ICs and Systems, THERMINIC 2012
Y2 - 25 September 2012 through 27 September 2012
ER -