Electronic Speckle Pattern Interference technique for measuring thickness of metallic nano thin films

•This paper demonstrates the use of ESPI method to measure the thickness of nano-sized metallic thin films.•Calculated thickness values via ESPI method are in good agreement with the values measured using profilometer.•The least thickness measured by this method is ~ 52 ± 3.1 nm.•The z-axis resoluti...

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Bibliographic Details
Main Authors: Bhagat, N.B., Padghan, P.P., Kesarwani, R., Khare, A., Alti, K.M.
Format: Conference Proceeding
Language:English
Subjects:
Electronic Speckle Pattern Interference
Metallic thin films
Surface Profiles
Surface roughness
Thickness Measurement
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Summary:•This paper demonstrates the use of ESPI method to measure the thickness of nano-sized metallic thin films.•Calculated thickness values via ESPI method are in good agreement with the values measured using profilometer.•The least thickness measured by this method is ~ 52 ± 3.1 nm.•The z-axis resolution of the used method is at par with other expensive microscopy techniques like atomic force microscopy.•Therefore, a low-cost alternative to expensive microscopy techniques is presented in this paper as far as z-axis is concern.•Surface roughness of thin films can also be calculated using retrieved surface profiles and they are also found to be in the nanometer range. Electronic Speckle Pattern Interference (ESPI) is a non-contact optical technique generally used for the measurement of surface deformations of various kinds. With the help of phase retrieval algorithms, phase of the deformed object is calculated in this method which can be then converted into displacement information. This paper demonstrates the use of ESPI method to measure the thickness of some nano-sized metallic thin films. Calculated thickness values are in good agreement with the values measured via Profilometer. The least thickness (z-axis) measured by this method is ~ 52 ± 3.1 nm. The z-axis resolution of the used method is at par with other expensive microscopy techniques like atomic force microscopy. Therefore, a low-cost alternative to expensive microscopy techniques is presented in this paper as far as z-axis is concern. Surface roughness of thin films can also be calculated using retrieved surface profiles and they are also found to be in the nanometer range.
ISSN:2214-7853
2214-7853
DOI:10.1016/j.matpr.2021.07.301