posted on 2024-12-04, 17:44authored byThang
Q. Tran, Sayyam Deshpande, Smita Shivraj Dasari, Kailash Arole, Denis Johnson, Yufan Zhang, Ethan M. Harkin, Abdoulaye Djire, Hang Li Seet, Sharon Mui Ling Nai, Micah J. Green
Here we demonstrate
direct ink write (DIW) additive manufacturing
of carbon nanotube (CNT)/phenolic composites with heat dissipation
and excellent electromagnetic interference (EMI) shielding capabilities
without curing-induced deformation. Such polymer composites are valuable
for protecting electronic devices from overheating and electromagnetic
interference. CNTs were used as a multifunctional nanofiller to improve
electrical and thermal conductivity, printability, stability during
curing, and EMI shielding performance of CNT/phenolic composites.
Different CNT loadings, curing conditions, substrate types, and sample
sizes were explored to minimize the negative effects of the byproducts
released from the cross-linking reactions of phenolic on the printed
shape integrity. At a CNT loading of 10 wt %, a slow curing cycle
enables us to cure printed thin-walled CNT/phenolic composites with
highly dense structures; such structures are impossible without a
filler. Moreover, the electrical conductivity of the printed 10 wt
% CNT/phenolic composites increased by orders of magnitude due to
CNT percolation, while an improvement of 92% in thermal conductivity
was achieved over the neat phenolic. EMI shielding effectiveness of
the printed CNT/phenolic composites reaches 41.6 dB at the same CNT
loading, offering a shielding efficiency of 99.99%. The results indicate
that high CNT loading, a slow curing cycle, flexible substrates, and
one thin sample dimension are the key factors to produce high-performance
3D-printed CNT/phenolic composites to address the overheating and
EMI issues of modern electronic devices.