Orientation dependent physical transport behavior and the micro-mechanical response of ZnO nanocomposites induced by SWCNTs and graphene: importance of intrinsic anisotropy and interfaces

Carbon nanotubes (CNTs) and graphene (G) possess superior thermal transport properties, large electron mobility, and excellent mechanical properties. However, their intrinsic transport and mechanical anisotropy can potentially have significant consequences for a composite system. We show in this wor...

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Published in:Journal of materials chemistry. C, Materials for optical and electronic devices Materials for optical and electronic devices, 2019, Vol.7 (5), p.1208-1221
Main Authors: Liang, Xin, Yang, Yuqing, Dai, Feihu, Wang, Changan
Format: Article
Language:English
Subjects:
Anisotropy
Carbon
Conduction heating
Conductive heat transfer
Cross-sections
Electron mobility
Energy dissipation
Figure of merit
Fillers
Fracture toughness
Graphene
Heat conductivity
Mechanical analysis
Mechanical properties
Microhardness
Microscopy
Nanocomposites
Orientation
Plasma sintering
Position measurement
Power factor
Pressing
Raman spectra
Single wall carbon nanotubes
Temperature dependence
Thermal conductivity
Thermal diffusivity
Thermal resistance
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Summary:Carbon nanotubes (CNTs) and graphene (G) possess superior thermal transport properties, large electron mobility, and excellent mechanical properties. However, their intrinsic transport and mechanical anisotropy can potentially have significant consequences for a composite system. We show in this work that adding these “high-performance” carbon materials may not necessarily improve certain properties as expected. We synthesize a series of SWCNT/ZnO and G/ZnO bulk nanocomposites using spark plasma sintering. Electron microscopy investigations reveal that SWCNTs and graphene prefer to align in the plane normal to the pressing direction. We find that the thermal conductivity and electron mobility along the sample cross-sectional direction of SWCNT/ZnO and G/ZnO are substantially lower than those of pure ZnO. The thermoelectric power factor and the figure of merit also exhibit strong orientation dependence. Four types of thermal interfaces (ZnO/SWCNT Axial , ZnO/SWCNT Radial , ZnO/G In-plane , and ZnO/G Cross-plane ) exist in these nanocomposites, and their corresponding interfacial thermal (Kapitza) resistance can differ by one order of magnitude. These results provide important implications for thermal management materials where CNTs and graphene are often chosen as thermal fillers to improve heat conduction and dissipation. The noticeable orientation dependence of micro-indentation hardness and fracture toughness observed in some nanocomposites implies the intrinsic mechanical anisotropy in SWCNTs and graphene. Our findings suggest that for a variety of energy, functional, and structural applications, the intrinsic anisotropy, alignment and arrangement of these low-dimensional carbon materials, as well as the carbon/matrix interfaces formed in the composite microstructure, are important factors to be considered and optimally controlled to achieve the desired performance.
ISSN:2050-7526
2050-7534
DOI:10.1039/C8TC05148H