Next-generation 2D optical strain mapping with strain-sensing smart skin compared to digital image correlation.

This study reports next generation optical strain measurement with "strain-sensing smart skin" (S) and a comparison of its performance against the established digital image correlation (DIC) method. S measures strain-induced shifts in the emission wavelengths of single-wall carbon nanotubes embedded in a thin film on the specimen. The new S film improves spectral uniformity of the nanotube sensors, avoids the need for annealing at elevated temperatures, and allows for parallel DIC measurements. Noncontact strain maps measured with the S films and point-wise scanning were directly compared to those from DIC on acrylic, concrete, and aluminum test specimens, including one with subsurface damage. Strain features were more clearly revealed with S than with DIC. Finite element method simulations also showed closer agreement with S than with DIC results. These findings highlight the potential of S strain measurement technology as a promising alternative or complement to existing technologies, especially when accumulated strains must be detected in structures that are not under constant observation.