This work describes the heat transfer process from a heated microcantilever to a substrate. A platinum-resistance thermometer with a 140nm width was fabricated on a SiO2-coated silicon substrate. The temperature coefficient of resistance estimated from the measurement was 7×104K1, about one-fifth of the bulk value of platinum. The temperature distribution on the substrate was obtained from the thermometer reading, as the cantilever raster scanned the substrate. Comparison between the measurement and calculation reveals that up to 75% of the cantilever power is directly transferred to the substrate through the air gap. From the force-displacement experiment, the effective tip-specimen contact thermal conductance was estimated to be around 40nWK. The findings from this study should help understand the thermal interaction between the heated cantilever and the substrate, which is essential to many nanoscale technologies using heated cantilevers.

Issue Section:
Micro/Nanoscale Heat Transfer
Keywords:
atomic force microscope, heated microcantilever, micro-∕nanoscale heat transfer, nanoscale thermometer, cantilevers, temperature distribution, thermal resistance, thermometers
Topics:
Cantilevers, Heat transfer, Temperature, Thermometers, Temperature distribution
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