期刊
CHEMICAL ENGINEERING JOURNAL
卷 439, 期 -, 页码 -出版社
ELSEVIER SCIENCE SA
DOI: 10.1016/j.cej.2022.134516
关键词
Graphene oxide; Biomass-derivatives; Bionic design; Fire protection; Fire early warning
资金
- Australian Research Council Training Centre in Fire Retardant Materials and Safety Technologies [IC170100032]
- Australian Research Council Discovery Early Career Researcher Award [DE190101176]
- International Collaboration Programs of Guangdong Province [2020A0505100010]
This study presents a new route for the design and development of environmentally friendly fireproof and fire alarm materials based on the effective utilization of natural biomass-derivatives. By constructing synergistic interactions among graphene oxide nanosheets, phosphorylated-cellulose nanofibrils, and tannic acid molecules, a hybrid interconnected network with a hierarchical nacre-like structure was achieved. It exhibited improved mechanical properties, good structural stability, excellent flame retardancy, and ultrasensitive fire alarm functions. Furthermore, this network can act as an effective flame-retardant nanocoating to significantly improve the flame retardancy of combustible PU foam materials.
Effective utilization of natural biomass-derivatives for developing sustainable, mechanically robust, and fireproof materials remains a huge challenge in fire safety and prevention field. Herein, based on bionic design, the hybrid interconnected networks composed of two-dimensional (2D) graphene oxide (GO) nanosheets, renewable onedimensional (1D) phosphorylated-cellulose nanofibrils (P-CNFs) and tannic acid molecules (TA) were prepared via a green and facile evaporation-induced self-assembly strategy. Through construction of the multiple synergistic interactions among the TA, P-CNFs and GO, the optimized 1D/2D interconnected networks with hierarchical nacre-like structure were achieved and exhibited improved mechanical properties (tensile strength and Young's modulus up to -132 MPa and -7 GPa, i.e. -3.6 and -14 times higher than that of the pure GO paper), good structural stability in various environments (aqueous solutions with different pH values), excellent flame retardancy (keeping structural integrity after flame attack), and ultrasensitive fire alarm functions (e.g., ultrafast flame alarm time of < 1 s and sensitive fire warning responses). Further, such 1D/2D interconnected networks can act as effective flame-retardant nanocoatings to significantly improve the flame retardancy of combustible PU foam materials (e.g.,-48% decrease in peak heat release rate at only 10 wt% content). Based on the structure observation and analysis, the related synergistic reinforcing and flame-retardant mechanisms were proposed and clarified. Clearly, this work provides a new route for design and development of environmentally friendly fireproof and fire alarm materials based on utilization of natural biomass-derivatives.
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