Publication | Closed Access
Single Wall Carbon Nanotube/Polyethylene Nanocomposites: Thermal and Electrical Conductivity
379
Citations
24
References
2007
Year
Pe CrystallinityEngineeringCarbon NanotechnologyElectrical ConductivityPolymer NanocompositesThermal ConductivityCarbon-based MaterialPolymer CompositesThermal ConductionCarbon NanotubesMaterials ScienceElectrical EngineeringThermal TransportPolymer Nanostructured CompositesSwnt LoadingPe AlignmentNanomaterialsPolymer ScienceApplied PhysicsNanocompositeNanotubesThermal Property
The study investigates how SWNT loading, PE crystallinity, and alignment affect the thermal and electrical conductivities of SWNT/PE nanocomposites. Thermal conductivity is modeled as arising from a percolating SWNT network in the HDPE matrix. Isotropic SWNT/PE composites exhibit a marked rise in thermal conductivity with SWNT loading (1.8 W/mK in LDPE and 3.5 W/mK in HDPE at φ≈0.2), the HDPE increase being super‑additive and implying reduced interfacial resistance, while alignment of SWNT/HDPE further boosts conductivity due to the aligned PE matrix.
The thermal and electrical conductivities in nanocomposites of single walled carbon nanotubes (SWNT) and polyethylene (PE) are investigated in terms of SWNT loading, the degree of PE crystallinity, and the PE alignment. Isotropic SWNT/PE nanocomposites show a significant increase in thermal conductivity with increasing SWNT loading, having 1.8 and 3.5 W/mK at a SWNT volume fraction of φ ∼ 0.2 in low-density PE (LDPE) and high-density PE (HDPE), respectively. This increase in SWNT/HDPE is more than additive and suggests a reduction of the interfacial thermal resistance. Fitting the thermal conductivity data of the SWNT/HDPE nanocomposites with two models indicates that the thermal conductivity relies on a percolating SWNT network. Oriented SWNT/HDPE nanocomposites exhibit higher thermal conductivities, which are attributed primarily to the aligned PE matrix.
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