In the present work, we show an extension of the “nanobubble inflation” method developed by O’Connell and McKenna which uses an interferometric method to measure the topography of a large array of 5 μm sized nanometer thick films subjected to constant inflation pressures during which the bubbles grow or creep with time. Glass formation and glassy behavior remain as the important areas of investigation in soft matter physics with many aspects which are still not completely understood, especially at the nanometer size-scale. These results show the need to pay careful attention to instrument calibration and probe/surface interactions in order to improve the accuracy of surface characterization of surface roughness and topography. For example, there was a variation of up to 7% between techniques in the measurement of the depths of the etched features and artefacts were also visible at square edges. ![]() Comparison of the results showed that while the general shapes of the measured surface microstructures were similar, several differences were found. One was left bare and the other was prepared with a rough layer of hydroxyapatite before measuring at the chosen positions. Two samples were prepared on silicon wafers by marking them with a multi-scale pattern using a photoresist process of lithography from an optical mask, followed by reactive ion etching. In the present work, a comparison has been made between the results of two different systems using interference microscopy and AFM to make measurements at the same place on the same sample. ![]() While optical techniques can be used to rapidly measure large areas, significant variations can be found between results from different techniques on similar samples. Measuring surface roughness accurately at the micro and nano scale presents several challenges.
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