Thermal transport in graphene nanostructures
Graphene is an extraordinary material. Its electrical and thermal conductivities are among the highest ever measured for any material, with some experiments recording values higher than those of carbon nanotubes. These excellent transport properties make graphene a...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2012
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| Online Access: | http://hdl.handle.net/10356/49888 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Graphene is an extraordinary material. Its electrical and thermal conductivities are among
the highest ever measured for any material, with some experiments recording values higher
than those of carbon nanotubes. These excellent transport properties make graphene a
promising material in nanoelectronic applications. As the device feature sizes are downscaled
to accommodate a greater device packing density, the need for an efficient thermal extraction
system is increasingly dire. Graphene could be the solution to these problems.However there are many factors that can vitiate its thermal performance. Lattice
discontinuities such as material interfaces and structural defects scatter phonons and impede
thermal transport through the material. This affects the heat-extraction performance and in
turn diminishes the thermal and electrical reliability of the device. In this thesis, thermal
transport in graphene and graphene nanostructures is studied using molecular dynamics (MD)
simulation. In particular, structural and topological features, such as interfaces, atomic
vacancies, adatoms, and tears, are emulated, and their effects on thermal transport are
documented. Thermal phenomena in the diamond-graphene and carbon nanotube-graphene
nanostructures are examined in detail.A common analytical tool to calculate the interfacial thermal resistance (or thermal
boundary resistance) is the diffuse mismatch model. Although it is widely used, large
disparities still exist between its predicted results and experimental measurements. Theoretical
evaluation and MD simulation demonstrate the critical role of thermal flux in interfacial
thermal transport. An improved model, the flux-mediated diffuse mismatch model (FMDMM)
is then developed. |
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