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Abstract
Coefficient of thermal expansion (CTE) for thin film has been measured only from change in thickness because thin film has to be constrained on a solid substrate. However, thin film CTE shows different values depending on the supporting solid substrate. Here, a novel measurement method is suggested to quantitatively measure the in-plane thermal expansion of thin films floating on a water surface. In-plane thermal expansion of thin films on water surface is achieved by heating the water. The CTE is measured through a digital image correlation (DIC) technique. The DIC tracks displacement marks deposited on the film surface, and the in-plane thermal strain is defined as the change in distance between the patterns. The method can be applied to measure the CTE of polymer, metal, and graphene with a thickness ranging from a micrometer to one-atom-thickness. The in-plane thermal expansion of the polystyrene (PS) thin film decreased as the film thickness decreased. The negative CTE of graphene is also successfully explored without any substrate effects or complicated calculations. The CTE measurement method can provide understanding of the intrinsic thermal expansion behavior of thin films including emerging two-dimensional materials.
Highlights
Thin films may have physical properties different from those of bulk material
The Coefficient of thermal expansion (CTE) of the thin films was determined according to the in-plane thermal strain with respect to the temperature change
A thin film specimen on a water surface was prepared through fabrication, pattern deposition, peel-off, etching and transfer processes (Supplementary Fig. S1)
Summary
Thin films may have physical properties different from those of bulk material. One of the physical properties that shows a thickness dependence is CTE1,2. We present measurements of in-plane thermal strain on a water surface without any substrate constraints (Fig. 1a,b). The CTE of the thin films was determined according to the in-plane thermal strain with respect to the temperature change. Our method can be used to explore the in-plane thermal behavior of thin films without any constraints from adjacent solid substrates, thereby enabling the thin film to expand freely on water surface.
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