Wood sawdust waste-derived nano-cellulose as a versatile reinforcing agent for nano silica cement composites: a systematic study on its characterization and performance

Badawy, Amr H.; El-Feky, M.S.; El-Tair, Ahmed Maher; Kohail, Mohamed

doi:10.1038/s41598-023-39788-x

Sci Rep

2023

DOI: 10.1038/s41598-023-39788-x

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Wood sawdust waste-derived nano-cellulose as a versatile reinforcing agent for nano silica cement composites: a systematic study on its characterization and performance

Amr H. Badawy

M.S. El-Feky

Ahmed Maher El-Tair

et al.

Abstract: The development of sustainable construction materials is a pressing concern for researchers worldwide, as the cement industry is a major contributor to environmental degradation. The incorporation of nano-materials with cement composites has emerged as a promising solution to sustainable materials production. In this study, the effect of the addition of nano cellulose produced from wood sawdust waste on the performance of cement-based nano-silica composite was investigated. The nano-materials were incorporated… Show more

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Cited by 2 publications

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Nanocellulose: A novel pathway to sustainable agriculture, environmental protection, and circular bioeconomy

Ahmed,

Islam,

Antu

et al. 2025

International Journal of Biological Macromolecules

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Nanocellulose: A novel pathway to sustainable agriculture, environmental protection, and circular bioeconomy

Ahmed,

Islam,

Antu

et al. 2025

International Journal of Biological Macromolecules

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High early strength concrete incorporating waste derived nanomaterials for sustainable construction

Hamed,

Serag,

El-Attar

et al. 2024

Sci Rep

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This paper contributes to the expanding knowledge base on nanomaterial-enhanced cementitious composites, offering valuable insights for developing high-performance, sustainable concrete solutions. The study assessed the effects of three different types of nanomaterials—nano clay (NC), nano silica (NS), and nano cellulose (NCel)—on the compressive strength of high-early-strength concrete (HESC) through both experimental studies and a 23 factorial design. Incorporating nanomaterials into the HESC matrix led to a decrease in workability, with NCel demonstrating the least impact on this property across all studied replacement percentages. All HESC mixes containing nanomaterials exhibited higher compressive strength than the control mix (M mix) across all ages. The optimal percentages for compressive strength enhancement were 4.5% NC (33.43% increase at 3 days, 22.29% at 7 days, and 12.15% at 28 days), 4.5% NS (20.12%, 11.14%, and 4.89% respectively), and 0.0375% NCel (34.91%, 25.76%, and 13.46% respectively). The highest compressive strength was observed in the hybrid mix containing 4.5% NC and 0.0375% NCel, yielding strength enhancements of 35.7%, 26%, and 12.75% compared to the M mix. Statistical analysis indicated that nano cellulose had the most significant contribution to enhancing compressive strength, followed by nano clay. The mathematical models derived from the statistical analyses provide a reliable means of predicting the compressive strength of HESC at 3, 7, and 28 days based on nanomaterial content. Contour plots illustrated the optimization of compressive strength across different nanomaterial contents at each age. In summary, the findings underscore the potential of waste-derived nanomaterials to enhance the performance of HESC, paving the way for innovative waste utilization strategies in construction. The study emphasizes the importance of reducing curing times, improving structural durability, and minimizing the environmental impact associated with concrete production.

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Wood sawdust waste-derived nano-cellulose as a versatile reinforcing agent for nano silica cement composites: a systematic study on its characterization and performance

Cited by 2 publications

References 69 publications

Nanocellulose: A novel pathway to sustainable agriculture, environmental protection, and circular bioeconomy

Nanocellulose: A novel pathway to sustainable agriculture, environmental protection, and circular bioeconomy

High early strength concrete incorporating waste derived nanomaterials for sustainable construction

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