Abstract
Elastomers are one of the most important materials in modern society because of the inherent viscoelastic properties due to their cross-linked polymer chains. Their vibration-absorbing and adhesive properties are especially useful and thus utilized in various applications, for example, tires in automobiles and bicycles, seismic dampers in buildings, and seals in a space shuttle. Thus, the nondestructive inspection of their internal states such as the internal deformation is essential in safety. Generally, industrial elastomers include various kinds of additives, such as carbon blacks for reinforcing them. The additives make most of them opaque in a wide spectral range from visible to mid-infrared, resulting in that the nondestructive inspection of the internal deformation is quite difficult. Here, we demonstrate transmission terahertz polarization spectroscopy as a powerful technique for investigating the internal optical anisotropy in optically opaque elastomers with conductive additives, which are transparent only in the terahertz frequency region. The internal deformation can be probed through the polarization changes inside the material due to the anisotropic dielectric response of the conductive additives. Our study about the polarization-dependent terahertz response of elastomers with conductive additives provides novel knowledge for in situ, nondestructive evaluation of their internal deformation.
Highlights
Drawing ratio relatively small in comparison to that of visible light, they possess high transmittance, which enables us to access the internal states of opaque polymeric materials
We report on the large optical anisotropy of loaded and unloaded fluoroelastomer (FKM) with carbon black (CB) fillers as revealed by PS THz-TDS with a transmission configuration; we discuss the physical origin of the optical anisotropy
The rotation of the slow optic axis is well reproduced by Monte Carlo (MC) simulations, which are based on the dominant impact of the orientational distribution of the CB aggregates on the birefringence
Summary
Drawing ratio relatively small in comparison to that of visible light, they possess high transmittance, which enables us to access the internal states of opaque polymeric materials. The strong influence of carbon-based additives on the optical properties of polymeric composite materials within the terahertz frequency region has been reported using terahertz spectroscopy[13,15,16,17,18,19,20,23]. The frequency dependence of the complex refractive index indicates that the anisotropic orientation of CB aggregates is the origin of the anisotropic optical responses, including birefringence. We measure the external stress dependence of birefringent properties in the FKM samples with different angles between the slow optic axis and the stretching direction. The well-reproduced fitting supports the claim that the anisotropic shape and the anisotropic dielectric responses of the CB aggregates in the terahertz frequency region are the origin of the optical anisotropy of the FKM samples
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