High-Temperature Sensing Based on GAWBS In Silica Single-Mode Fiber

High temperature detection is a constant challenge for condition monitoring under harsh environments in optical fiber sensors research. In this study, the temperature response characteristics of guided acoustic wave Brillouin scattering (GAWBS) spectra in silica single-mode fiber (SMF) up to 800 degrees C are experimentally investigated, demonstrating the feasibility of the method for high-temperature monitoring. With increasing temperature, the resonance frequency of GAWBS spectra increases in a nearly linear manner, with linearly fitted temperature-dependent frequency shift coefficients of 8.19 kHz/degrees C for TR2,7 mode and 16.74 kHz/degrees C for R-0,R-4 mode. More importantly, the linewidth of the GAWBS spectra is observed to narrow down with increasing temperature with a linearly fitted rate of -6.91 x 10(-4)/degrees C for TR2,7 modes and -8.56 x 10(-4)/degrees C for R-0,R-4 modes. The signal-to-noise ratio of the GAWBS spectra induced by both modes increase by more than 3 dB when the temperature rises from 22 degrees C to 800 degrees C, which indicates that the proposed sensing scheme has better performance in high-temperature environments, and are particularly suitable for sensing applications in extreme environments. This study confirms the potential of high-temperature sensing using only GAWBS in silica fibers without any complex micromachining process, which has the advantages of strong mechanical strength, simple structure, easy operation, and low cost.

Automated summary

In this study, the temperature response of guided acoustic wave Brillouin scattering (GAWBS) spectra in silica single-mode fiber (SMF) was experimentally investigated up to 800 degrees C, demonstrating its feasibility for high-temperature monitoring. The resonance frequency of GAWBS spectra increases linearly with temperature, with temperature-dependent frequency shift coefficients of 8.19 kHz/degrees C and 16.74 kHz/degrees C for the two analyzed modes. Additionally, the linewidth of GAWBS spectra decreases linearly with temperature, with temperature-dependent rates of -6.91 x 10(-4)/degrees C and -8.56 x 10(-4)/degrees C for the two modes. The proposed sensing scheme exhibits improved performance and signal-to-noise ratio in high-temperature environments, making it suitable for sensing applications in extreme conditions.