This article investigates the influence of temperature on the total ionizing dose (TID) effects in optical fibers. Radiation induced attenuation (RIA) spectra at 1310 nm were measured in G652, OM, PM1016-C, and homemade B1-R fibers during and after γ-irradiation at different temperatures. The B1-R fibers were doped with varying Al2O3 content in their core and coating layers. Experimental results show that the B1-R fibers have significant lower losses compared with the other three fibers. At a temperature of 25° and a TID does of 50 kGy, the B1-R fiber showed an RIA of only 1.35 dB/Km, while the other three fibers exhibit a minimum loss exceeding 6.44 dB/Km. Furthermore, the B1-R fiber withstood an irradiation does 100 times higher than other optical fibers. For a fixed temperature, the attenuation in B1-R fibers recovered quickly after irradiation, reaching their minimum values approximately 15 days post-irradiation, whereas the other three optical fibers required more than 25 days to recover. This study also delves into the underlying mechanisms contributing to the radiation resistance of B1-R optical fibers. The findings presented in this work offer critical insights for the development of high-performance, radiation resistant fibers, rendering them suitable for deployment in challenging deep space environments characterized by intense radiation conditions.
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