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Microscale Imaging of Thermal Conductivity Suppression at Grain Boundaries

Eleonora Isotta, Shizhou Jiang, Gregory Moller, Alexandra Zevalkink, G. Jeffrey Snyder, Oluwaseyi Balogun

2023Advanced Materials59 citationsDOIOpen Access PDF

Abstract

Grain-boundary engineering is an effective strategy to tune the thermal conductivity of materials, leading to improved performance in thermoelectric, thermal-barrier coatings, and thermal management applications. Despite the central importance to thermal transport, a clear understanding of how grain boundaries modulate the microscale heat flow is missing, owing to the scarcity of local investigations. Here, thermal imaging of individual grain boundaries is demonstrated in thermoelectric SnTe via spatially resolved frequency-domain thermoreflectance. Measurements with microscale resolution reveal local suppressions in thermal conductivity at grain boundaries. Also, the grain-boundary thermal resistance - extracted by employing a Gibbs excess approach - is found to be correlated with the grain-boundary misorientation angle. Extracting thermal properties, including thermal boundary resistances, from microscale imaging can provide comprehensive understanding of how microstructure affects heat transport, crucially impacting the materials design of high-performance thermal-management and energy-conversion devices.

Topics & Concepts

Microscale chemistryGrain boundaryMaterials scienceThermal conductivityScanning thermal microscopyThermoelectric effectMisorientationThermalThermal resistanceThermoelectric materialsInterfacial thermal resistanceMicrostructureComposite materialThermodynamicsPhysicsMathematics educationMathematicsThermal properties of materialsAdvanced Thermoelectric Materials and DevicesThermal Radiation and Cooling Technologies
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