Abstract
Thermal transport in suspended graphene samples has been measured in prior works and this work with the use of a suspended electro-thermal micro-bridge method. These measurement results are analyzed here to evaluate and eliminate the errors caused by the extrinsic thermal contact resistance. It is noted that the room-temperature thermal resistance measured in a recent work increases linearly with the suspended length of the single-layer graphene samples synthesized by chemical vapor deposition (CVD), and that such a feature does not reveal the failure of Fourier’s law despite the increase in the reported apparent thermal conductivity with length. The re-analyzed apparent thermal conductivity of a single-layer CVD graphene sample reaches about 1680 ± 180 W m−1 K−1 at room temperature, which is close to the highest value reported for highly oriented pyrolytic graphite. In comparison, the apparent thermal conductivity values measured for two suspended exfoliated bi-layer graphene samples are about 880 ± 60 and 730 ± 60 Wm−1K−1 at room temperature, and approach that of the natural graphite source above room temperature. However, the low-temperature thermal conductivities of these suspended graphene samples are still considerably lower than the graphite values, with the peak thermal conductivities shifted to much higher temperatures. Analysis of the thermal conductivity data reveals that the low temperature behavior is dominated by phonon scattering by polymer residue instead of by the lateral boundary.
Highlights
Among many fascinating properties discovered in graphene,[1,2] its high basal-plane thermal conductivity (κ) has attracted broad interests because of the underlying two dimensional (2D) phonon transport physics and the potential for thermal management applications
The small resistance obtained at vanishing length for the chemical vapor deposition (CVD) graphene samples show that extrinsic contact thermal resistance and the intrinsic thermal boundary resistance between the suspended and supported graphene contributes up to ∼ 20% of the total sample thermal resistance when the suspended length is more than 5 micrometers long
This contact thermal resistance is not negligible, it is not the cause of the lower κ values measured by the electro-thermal method compared to some Raman measurement results, which are for temperatures higher than room temperature and subject to similar extrinsic and intrinsic contact thermal resistance
Summary
Our theoretical analysis of the experimental data indicates that surface polymer residue instead of lateral boundaries suppresses the κ of these suspended graphene samples to be considerably lower than graphite values at low temperatures These findings suggest that there is still a need to experimentally observe large intrinsic κ and low peak temperature values in a clean graphene sample before the experimental results can be used for verifying various theoretical predictions of 2D phonon physics in clean suspended graphene, such as the peculiar length dependence and flexural phonon contributions
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