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- ItemAlF3-assisted flux growth of mullite whiskers and their application in fabrication of porous mullite-alumina monoliths(Amsterdam : Elsevier, 2021) Abdullayev, Amanmyrat; Klimm, Detlef; Kamutzki, Franz; Gurlo, Aleksander; Bekheet, Maged F.Mullite is a promising material with its competitive thermochemical and mechanical properties. Although mullite could be obtained by several synthesis methods, the flux method emerges with its advantages over other methods. However, obtaining mullite whiskers with a high aspect ratio and length for ceramic reinforcements is still challenging. In this work, mullite whiskers were grown from AlF3-assisted flux. The addition of AlF3 to flux salt not only decreases the formation temperature of mullite to as low as 700 °C and suppresses the formation of corundum side phase, but also increases the length and aspect ratio of the whiskers. The obtained mullite whiskers were used as reinforcement for porous alumina monoliths prepared by the freeze casting route and subsequent sintering at 1500 °C. The fabricated mullite-alumina monoliths show competitive compressive strength of 25.7 MPa while having as high as 70.6% porosity, which makes them a potential candidate for membrane applications.
- ItemImpact of rare earth doping on the luminescence of lanthanum aluminum silicate glasses for radiation sensing(Washington, DC : OSA, 2022) Shaw, Ruth E.; Kalnins, Christopher A. G.; Whittaker, Carly A.; Moffatt, Jillian E.; Tsiminis, Georgios; Klantsataya, Elizaveta; Ottaway, David; Spooner, Nigel A.; Litzkendorf, Doris; Matthes, Anne; Schwuchow, Anka; Wondraczek, Katrin; Ebendorff-Heidepriem, HeikeLarge core soft glass fibers have been demonstrated to be promising candidates as intrinsic fiber sensors for radiation detection and dosimetry applications. Doping with rare earth ions enhanced their radiation sensitivity. SiO2-Al2O3-La2O3 (SAL) glasses offer easy fabrication of large core fibers with high rare earth concentration and higher mechanical strength than soft glasses. This paper evaluates the suitability of the SAL glass type for radiation dosimetry based on optically stimulated luminescence (OSL) via a comprehensive investigation of the spectroscopic and dosimetric properties of undoped and differently rare earth doped bulk SAL glass samples. Due to the low intensity of the rare earth luminescence peaks in the 250–400 nm OSL detection range, the OSL response for all the SAL glasses is not caused by the rare earth ions but by radiation-induced defects that act as intrinsic centers for the recombination of electrons and holes produced by the ionizing radiation, trapped in fabrication induced defect centers, and then released via stimulation with 470 nm light. The rare earth ions interfere with these processes involving intrinsic centers. This dosimetric behavior of highly rare earth doped SAL glasses suggests that enhancement of OSL response requires lower rare earth concentrations and/or longer wavelength OSL detection range.