https://www.selleckchem.com/products/mv1035.html The present study reports on the microstructural evolution and room temperature plasticity of V(‑Si)‑B alloys with respect to the V solid solution (VSS)‑V3B2 phase region. To investigate the occurring effects systematically, different binary V‑B and ternary V‑Si‑B alloys were produced by conventional arc melting. Scanning electron microscope (SEM) analyses and X-ray diffraction (XRD) measurements were used to characterize the resulting as-cast microstructures. For the first time, the eutectic composition was systematically traced from the binary V‑B domain to the ternary V‑Si‑B system. The observations discover that the binary eutectic trough (VSS‑V3B2) seems to reach into the ternary system up to an alloy composition of V‑5Si‑9B. Room temperature compression tests were carried out in order to study the impact of single-phase and multi-phase microstructures on the strength and plasticity of binary and ternary alloys. The results indicate that the VSS phase controls the plastic deformability in the VSS‑V3B2 eutectic microstructure whereas the intermetallic V3B2 acts as a strong hardening phase.Prior research has demonstrated that distributed optical fiber sensors (DOFS) based on Rayleigh scattering can be embedded in carbon fiber/epoxy composite structures to rapidly detect temperature changes approaching 1000 °C, such as would be experienced during a high energy laser strike. However, composite structures often experience mechanical strains that are also detected during DOFS interrogation. Hence, the combined temperature and strain response in the composite can interfere with rapid detection and measurement of a localized thermal impulse. In this research, initial testing has demonstrated the simultaneous response of the DOFS to both temperature and strain. An embedded DOFS network was designed and used to isolate and measure a localized thermal response of a carbon fiber/epoxy composite to a low energy laser strike u