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Direct mapping of local Seebeck coefficient in 2D material nanostructures via scanning thermal gate microscopy

Harzheim, Achim, Evangeli, Charalambos, Oleg Kolosov, Pascal Gehring

2020Oxford University Research Archive (ORA) (University of Oxford)26 citationsOpen Access PDF

Abstract

Studying local variations in the Seebeck coefficient of materials is important for understanding and optimizing their thermoelectric properties, yet most thermoelectric measurements are global over a whole device or material, thus overlooking spatial divergences in the signal and the role of local variation and internal structure. Such variations can be caused by local defects, metallic contacts or interfaces that often substantially influence thermoelectric properties, especially in two dimensional materials. Here, we demonstrate scanning thermal gate microscopy, a non-destructive method to obtain high resolution 2-dimensional maps of the thermovoltage, to study graphene samples. We demonstrate the efficiency of this newly developed method by measuring local Seebeck coefficient in a graphene ribbon and in a junction between single-layer and bilayer graphene.

Topics & Concepts

Seebeck coefficientScanning thermal microscopyMaterials scienceNanostructureScanning electron microscopeMicroscopyThermalThermoelectric effectScanning probe microscopyThermal expansionNanotechnologyOptoelectronicsComposite materialOpticsNanoscopic scalePhysicsThermal conductivityThermodynamicsThermal properties of materialsGraphene research and applicationsAdvanced Thermoelectric Materials and Devices
Direct mapping of local Seebeck coefficient in 2D material nanostructures via scanning thermal gate microscopy | Litcius