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Measurement of thin film isotropic and anisotropic thermal conductivity using 3ω and thermoreflectance imaging.
| Content Provider | CiteSeerX |
|---|---|
| Author | Maize, K. Ezzahri, Y. Wang, X. Singer, S. Majumdar, A. Shakouri, A. |
| Abstract | The 3ω method is a well established technique for measuring thermal conductivity of thin films and substrates. The method extracts thermal conductivity by measuring temperature response when current flows through a metal strip heater deposited on the material’s surface. The metal strip is used both as heat source and temperature sensor. An important factor in the accuracy of 3ω measurements is that the current should be confined to the metal strip resistor and any leakage to the substrate will invalidate the results. This is because the heat source would no longer be localized on the surface and also because any Schottky behavior at metal/semiconductor interface will create nonlinearities that affect the 3ω signal substantially. These problems are especially important at high temperatures where thermionic emission of electrons through oxide insulation layer becomes important. In this paper we propose thermoreflectance imaging as an additional method to determine thermal conductivity of thin film materials. Because thermoreflectance measures temperatures optically, the method is less dependent on the electrical properties of the metal heater. Additionally, the temperature profile near the heat source can be used to ensure there is no defect in the thin film metal heater. Theory is presented demonstrating thermoreflectance can also be used to measure anisotropic in-plane and cross-plane thermal conductivity in thin films. Preliminary thermoreflectance measurements were analyzed at various locations on the surface of isotropic, InGaAs and anisotropic ScN/ZrN superlattice thin film 3ω test samples. Experimental results are in agreement with simulated temperature distributions. |
| File Format | |
| Access Restriction | Open |
| Subject Keyword | Thermoreflectance Imaging Heat Source Thermal Conductivity Anisotropic Thermal Conductivity Using Thin Film Isotropic Thin Film Temperature Sensor Material Surface Metal Strip Resistor Thermionic Emission Additional Method Oxide Insulation Layer Anisotropic In-plane Electrical Property High Temperature Important Factor Thin Film Material Cross-plane Thermal Conductivity Various Location Simulated Temperature Distribution Thin Film Metal Heater Metal Strip Metal Strip Heater Schottky Behavior Temperature Response Metal Semiconductor Interface Temperature Profile Metal Heater Test Sample Preliminary Thermoreflectance Measurement Thermoreflectance Measure Experimental Result |
| Content Type | Text |
| Resource Type | Article |
