Flame-retardant cellulose-aerogel composite from agriculture waste for building insulation

•The fire-retardant cellulose aerogel insulation nanocomposites are derived from wheat straw and silica aerogel.•The as-prepared materials show a low thermal conductivity of 24.1 mW/m.K, high flexural modulus of 736 MPa, hydrophobicity with a water contact angle of 110.42°, and excellent fire retard...

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Bibliographic Details
Published in:Applied materials today 2024-02, Vol.36 (C), p.102080, Article 102080
Main Authors: Sarkar, Arpita, Islam, Abdullah, Zhu, Long, Ren, Shenqiang
Format: Article
Language:English
Subjects:
Biogenic materials
Fire retardant cellulose-aerogel composites
Thermal insulation
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Summary:•The fire-retardant cellulose aerogel insulation nanocomposites are derived from wheat straw and silica aerogel.•The as-prepared materials show a low thermal conductivity of 24.1 mW/m.K, high flexural modulus of 736 MPa, hydrophobicity with a water contact angle of 110.42°, and excellent fire retardancy.•This work provides an effective method for the synthesis of fire-retardant biogenic thermal insulation materials. Bio-based thermal insulation materials are in high demand due to their availability, reproducibility, and carbon-sequestration nature. However, high flammability, moisture condensation, and high thermal conductivity of biogenic material are major concerns for sustainable building applications. In this study, we report the fire-retardant cellulose aerogel insulation nanocomposites derived from wheat straw and silica aerogel, in which sodium bicarbonate improves its fire retardancy. We combined blended straw fibers and hammermilled straw fibers to create a structural hierarchy composite. The blended straw, with its longer and thicker size, served as reinforcement, while the hammermilled straw fibers acted as filler. This hierarchical structure was further integrated with aerogel for applications in green buildings. The as-prepared materials show a low thermal conductivity of 24.1 mW/m.K, high flexural modulus of 736 MPa, hydrophobicity with a water contact angle of 110.42°, and excellent fire retardancy. Overall, this work provides an effective method for the synthesis of fire-retardant biogenic thermal insulation materials and shows a promising way for next-generation bio-based insulation materials. [Display omitted]
ISSN:2352-9407
2352-9415
DOI:10.1016/j.apmt.2024.102080