MEASUREMENT OF THERMOELECTRIC AND THERMAL TRANSPORT PROPERTIES OF SINGLE-MOLECULE JUNCTIONS
The study of thermoelectric and thermal properties of single-molecule junctions is expected to provide important insights into the relationship between molecular structure and the resultant transport properties. Computational studies have predicted several interesting thermoelectric effects in molecular junctions including the possibility of simultaneously achieving a large electrical conductance and Seebeck coefficient. The experimental techniques required to study these interesting thermoelectric properties−at the single/few molecule level−have been developed recently and are described in detail here. Thermal transport properties of single-molecule/polymer junctions have also been computationally studied and various interesting predictions have been made. Although pioneering measurements of thermal transport in monolayers of molecules and polymer nanofibers have been accomplished, to date it has not been possible to probe heat transfer at the single-molecule/polymer chain level. Here, we outline the challenges in performing such measurements and suggest possible approaches to overcome them.
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Illustration of composite TIMs with a percolation of spherical nanoparticles, and high aspect ratio nanowires. NANOSTRUCTURED THERMAL INTERFACES
Photograph of copper/diamond sintered wick structure. RECENT ADVANCES IN TWO-PHASE THERMAL GROUND PLANES
The microchannel with a single pillar used by Jung et al., and an SEM image of the pillar with a flow control slit at 180 deg (facing downstream). ADVANCED CHIP-LEVEL LIQUID HEAT EXCHANGERS
Schematics of thermal boundary conductance calculations. NONEQUILIRIUM MOLECULAR DYNAMICS METHODS FOR LATTICE HEAT CONDUCTION CALCULATIONS
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