A three-dimensional nanostructure of graphite intercalated by carbon nanotubes with high cross-plane thermal conductivity and bending strength

A three-dimensional graphite consolidated composite (GCC) was prepared by the intercalation of carbon nanotubes (CNTs) at the interlayer of expanded graphite (EG) using chemical vapor deposition followed by hot-pressing. The intercalation of well-dispersed CNTs was attributed to the dispersion of ca...

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Bibliographic Details
Published in:Carbon (New York) 2014-10, Vol.77, p.1054-1064
Main Authors: Feng, Wei, Qin, Mengmeng, Lv, Peng, Li, Jianpeng, Feng, Yiyu
Format: Article
Language:English
Subjects:
Bend strength
Carbon nanotubes
Catalysis
Chemical vapor deposition (including plasma-enhanced cvd, mocvd, etc.)
Chemistry
Cross-disciplinary physics: materials science
rheology
Exact sciences and technology
General and physical chemistry
Graphite
Heat transfer
Intercalation
Materials science
Methods of deposition of films and coatings
film growth and epitaxy
Nanoscale materials and structures: fabrication and characterization
Nanotubes
Physics
Surface physical chemistry
Theory of reactions, general kinetics. Catalysis. Nomenclature, chemical documentation, computer chemistry
Thermal conductivity
Three dimensional
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Summary:A three-dimensional graphite consolidated composite (GCC) was prepared by the intercalation of carbon nanotubes (CNTs) at the interlayer of expanded graphite (EG) using chemical vapor deposition followed by hot-pressing. The intercalation of well-dispersed CNTs was attributed to the dispersion of catalysts at the interface of EG based on vacuum impregnation. The crystal orientation in the cross-plane direction of CNT/GCC blocks was remarkably improved by the intercalation of CNTs. The density of CNT/GCC was also increased by intercalating CNTs into the pore space of layered graphite. Thermal conductivity and bending strength of CNT/GCC were controlled by the growth time of CNTs and hot-pressing pressure. CNT/GCC showed a maximum cross-plane thermal conductivity (λ⊥) of 24.3 Wm−1K−1, which is threefold higher than that of GCC (6.2Wm−1K−1). A remarkable increase in λ⊥ was attributed to efficient heat flow of CNTs bridging graphite layers in the cross-plane direction and good contact between nanotubes and graphite layers. Furthermore, the cross-plane bending strength (σb⊥) of CNT/GCC up to 46MPa is 48.4% higher than that of GCC at 31MPa due to the combination of strong pull-out effect of high-density long nanotubes and the decreased open porosity.
ISSN:0008-6223
1873-3891
DOI:10.1016/j.carbon.2014.06.021