Manufacturing silica aerogel and cryogel through ambient pressure and freeze drying

Achieving a mesoporous structure in superinsulation materials is pivotal for guaranteeing a harmonious relationship between low thermal conductivity, high porosity, and low density. Herein, we report silica-based cryogel and aerogel materials by implementing freeze-drying and ambient-pressure-drying...

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Bibliographic Details
Published in:RSC advances 2022-08, Vol.12 (33), p.21213-21222
Main Authors: Di Luigi, Massimigliano, Guo, Zipeng, An, Lu, Armstrong, Jason N, Zhou, Chi, Ren, Shenqiang
Format: Article
Language:English
Subjects:
Chemistry
Composite materials
Compressive properties
Fiber reinforced materials
Flame retardants
Freeze drying
Heat conductivity
Heat transfer
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Mechanical properties
Modulus of elasticity
Nanocomposites
Porosity
Pressure
Silica aerogels
Specific surface
Surface area
Thermal conductivity
Thermal insulation
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Summary:Achieving a mesoporous structure in superinsulation materials is pivotal for guaranteeing a harmonious relationship between low thermal conductivity, high porosity, and low density. Herein, we report silica-based cryogel and aerogel materials by implementing freeze-drying and ambient-pressure-drying processes respectively. The obtained freeze-dried cryogels yield thermal conductivity of 23 mW m −1 K −1 , with specific surface area of 369.4 m 2 g −1 , and porosity of 96.7%, whereas ambient-pressure-dried aerogels exhibit thermal conductivity of 23.6 mW m −1 K −1 , specific surface area of 473.8 m 2 g −1 , and porosity of 97.4%. In addition, the fiber-reinforced nanocomposites obtained via freeze-drying feature a low thermal conductivity (28.0 mW m −1 K −1 ) and high mechanical properties (∼620 kPa maximum compressive stress and Young's modulus of 715 kPa), coupled with advanced flame-retardant capabilities, while the composite materials from the ambient pressure drying process have thermal conductivity of 28.8 mW m −1 K −1 , ∼200 kPa maximum compressive stress and Young's modulus of 612 kPa respectively. The aforementioned results highlight the capabilities of both drying processes for the development of thermal insulation materials for energy-efficient applications. Ambient pressure and freeze drying techniques enable silica aerogel and cryogel insulation composites.
ISSN:2046-2069
2046-2069
DOI:10.1039/d2ra03325a