Photoacoustic thermal characterization of low thermal diffusivity thin films

The photoacoustic measurement technique is a powerful yet underrepresented method to characterize the thermal transport properties of thin films. For the case of isotropic low thermal diffusivity samples, such as glasses or polymers, we demonstrate a general approach to extract the thermal conductivity with a high degree of significance. We discuss in particular the influence of thermal effusivity, thermal diffusivity, and sample layer thickness on the significance and accuracy of this measurement technique. These fundamental thermal properties guide sample and substrate selection to allow for a feasible thermal transport characterization. Furthermore, our data evaluation allows us to directly extract the thermal conductivity from this transient technique, without separate determination of the volumetric heat capacity, when appropriate boundary conditions are fulfilled. Using silica, poly(methyl methacrylate) (PMMA) thin films, and various substrates (quartz, steel, and silicon), we verify the quantitative correctness of our analytical approach.

Automated summary

The photoacoustic measurement technique is a powerful method for characterizing thermal transport properties of thin films, particularly in isotropic low thermal diffusivity samples. Significant influence of thermal effusivity, thermal diffusivity, and sample layer thickness on the measurement accuracy is discussed. The method allows for direct extraction of thermal conductivity without separate determination of heat capacity when appropriate boundary conditions are met.