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24-12-2022 | Original Research

One-pot fabrication of bio-based hydrophobic and flame-retardant coating for cotton fabric

Authors: Wenhui Rao, Junjiao Shi, Meini Yang, Feihao Yang, Tao Wu, Chuanbai Yu, Ming-Jun Chen, Hai-Bo Zhao

Published in: Cellulose | Issue 3/2023

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Abstract

The facile fabrication of eco-friendly flame-retardant coatings with high efficiency, hydrophilicity, and good softness for cotton fabrics is imperative, but still challenging. Here, we construct an environmentally friendly hydrophobic and fire-safety coating on cotton fabric through a one-pot sol-gel method based on biobased phytic acid (PA), tannic acid (TA), and vinyl trimethoxysilane (VTS). In this system, PA as an acid source, TA as a charring agent, together with VTS as a silicon source construct a phosphorus/nitrogen/silicon-containing high-efficiency hybrid flame-retardant system. Under an ultralow loading of 9.5 wt%, the coating can enable cotton fabric with self-extinguishing behavior during vertical burning test, a high limiting oxygen index of 29%, significantly reduced heat release (~ 68.9%), and almost negligible smoke release (down to 0). Additionally, TA can react with PA and VTS to largely reduce the hydrophilic groups during the sol-gel process, while the presence of hydrophobic vinyl functional groups further turns the hydrophilic surface of cotton fabric to a hydrophobic surface with a water contact angle of 117.2°. In addition, the physical properties of the resultant cotton fabrics are almost unchanged. This work offers new perspective for facile fabricating hydrophobic coatings with the merits of satisfactory flame retardancy, environmental friendliness, along with softness.

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Title: One-pot fabrication of bio-based hydrophobic and flame-retardant coating for cotton fabric
Authors: Wenhui Rao
Junjiao Shi
Meini Yang
Feihao Yang
Tao Wu
Chuanbai Yu
Ming-Jun Chen
Hai-Bo Zhao
Publication date: 24-12-2022
Publisher: Springer Netherlands
Published in: Cellulose / Issue 3/2023
Print ISSN: 0969-0239
Electronic ISSN: 1572-882X
DOI: https://doi.org/10.1007/s10570-022-05005-7

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