Optimization of Alumina and Aluminosilicate Aerogel Structure for High‐Temperature Performance

Hurwitz, Frances I.; Gallagher, M.; Olin, Tracy C.; Shave, Molly K.; Ittes, Marlyssa Α.; Olafson, Katy N.; Fields, Meredith; Guo, Hongbo; Rogers, Richard B.

doi:10.1111/ijag.12070

Cited by 44 publications

(26 citation statements)

References 36 publications

(91 reference statements)

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“…Prior investigations of alumina and aluminosilicate systems have shown the potential for stabilizing a mesoporous aerogel structure to temperatures of 1100°C‐1200°C 16,17 . The current study investigates the synthesis of yttrium, ytterbium, and co‐doped zirconia aerogels and the influence of phase stability in maintaining a porous microstructure.…”

Section: Introductionmentioning

confidence: 99%

Phase development and pore stability of yttria‐ and ytterbia‐stabilized zirconia aerogels

et al. 2020

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High-porosity yttria-and ytterbia-stabilized zirconia aerogels offer the potential of extremely low thermal conductivity materials for high-temperature applications. Yttria-and ytterbia-doped zirconia aerogels were synthesized using a sol-gel approach over the dopant range of 0-20 atomic percent. Surface area, pore volume, and morphology of the as-dried aerogels and materials thermally exposed for short periods of time to temperatures up to 1200°C were characterized by nitrogen physisorption, scanning and transmission electron microscopy, and X-ray diffraction. The aerogels as supercritically dried all were X-ray amorphous. At a 5% dopant level, a tetragonal structure with a smaller monoclinic phase developed on thermal exposure. Mixed tetragonal and cubic phases or predominantly cubic materials were observed at higher dopant levels, depending on the dopant level, temperature and exposure time. The formation of crystalline phases was accompanied by loss of surface area and pore volume, although some mesoporous structure was maintained on short-term exposure to 1000°C. Incorporation of the smaller Yb atom into the lattice structure resulted in smaller lattice dimensions on crystallization than was seen with Y doping and favored a more highly equiaxed structure. Aerogels synthesized with 15% Y maintained the smallest particle size without evidence of sintering at 1100°C.

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Section: Introductionmentioning

confidence: 99%

Phase development and pore stability of yttria‐ and ytterbia‐stabilized zirconia aerogels

et al. 2020

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“…At a temperature of 1000 1C, a small amount of large pores with diameters greater than 200 nm emerge in the composite, which stems from the densification and sintering of γ-Al 2 O 3 particles. As the temperature is increased to 1200 1C, the uniform agglomerated structures primarily contain mullite with small amounts of γ-Al 2 O 3 particles, which is probably caused by the growth of mullite grains [11,25]. However, the SEM images reveal that the resulting composite aerogel after heat treatment at 1200 1C presents disordered, porous structures of a typical colloidal gel, and that nanoparticles are uniformly distributed to form a framework surrounded with irregular pores [26,27].…”

Section: Resultsmentioning

confidence: 99%

“…Because the formed mono-hydroxide is the only material that can be peptized to a clear sol, a highly complex procedure is needed to obtain a clear solution [8][9][10]. Hurwitz et al [11] directly employed boehmite powder as an alumina source to prepare Al 2 O 3 -SiO 2 aerogel. The specific surface area was as high as 33 m 2 /g at 1300 1C, whereas the phase transition of γ-Al 2 O 3 / η-Al 2 O 3 occurred as early as 600 1C.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of a novel Al2O3–SiO2 composite aerogel with high specific surface area at elevated temperatures using inexpensive inorganic salt of aluminum

Shao

Cui

et al. 2016

Ceramics International

119

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“…Fibre reinforced silica aerogel composite, with low thermal conductivity and high mechanical performance, expands its uses especially as an excellent thermal insulation material [1][2][3][4][5][6][7][8][9][10][11]. However, alumina-silica (Al 2 O 3 −SiO 2 ) aerogel, with high specific surface area, high porosity and high temperature stability [12][13][14][15][16][17], is attracting more increased interest in the field of thermal insulation application [18][19][20][21][22][23][24][25] at elevated temperature. As with SiO 2 aerogel, the Al 2 O 3 −SiO 2 aerogel is fragile and difficult to use directly.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of fibre reinforced Al2O3−SiO2 aerogel composite with high density uniformity via a facile high-pressure impregnation approach

Yang

Jiang

Feng

et al. 2017

PAC

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Alumina-silica (Al 2 O 3 −SiO 2) aerogel composite, with low density, low thermal conductivity and hightemperature stability, is attracting increased interest in the field of thermal insulation application. In this paper, a novel way to fabricate fibre reinforced Al 2 O 3 −SiO 2 aerogel composite via a facile high-pressure impregnation approach was reported. Two Al 2 O 3 −SiO 2 aerogel composites, HPe and LPe, were synthesized via high-pressure and low-pressure impregnation approach, respectively. The effects of the impregnation approach on the aerogel composites performance were studied, and the impregnation model was established. The results showed that the as-prepared HPe exhibited higher density uniformity, better high-temperature stability, higher specific surface area and lower thermal conductivity. It was also shown that the effect of impregnation approach on the mean density and morphology of the aerogel composites is negligible. However, the standard deviation of density (0.00857) and mean thickness shrinkage (9.98%) of HPe were 37.8% and 15.4% lower than that of LPe, respectively. The specific surface area (884.1 m 2 /g) of HPe was 43.5% higher than that of LPe. The thermal conductivity of HPe at 1100°C was 2.74% lower than that of LPe. The impregnation model of the aerogel composites presented that the density uniformity and thermal conductivity of HPe were improved obviously, because there were less large pores in HPe than in the LPe.

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Optimization of Alumina and Aluminosilicate Aerogel Structure for High‐Temperature Performance

Cited by 44 publications

References 36 publications

Phase development and pore stability of yttria‐ and ytterbia‐stabilized zirconia aerogels

Phase development and pore stability of yttria‐ and ytterbia‐stabilized zirconia aerogels

Synthesis of a novel Al2O3–SiO2 composite aerogel with high specific surface area at elevated temperatures using inexpensive inorganic salt of aluminum

Synthesis of fibre reinforced Al2O3−SiO2 aerogel composite with high density uniformity via a facile high-pressure impregnation approach

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