A novel cysteine-based flame retardant for biomass poplar wood density board

A novel reactive flame retardant based on L-cysteines containing P, N and S flame retardant elements was synthesized, and using its good water solubility, different concentrations of flame retardant poplar wood powder were prepared, and using the hot pressing process method, flame retardant density...

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Bibliographic Details
Published inEuropean journal of wood and wood products Vol. 82; no. 1; pp. 175 - 187
Main Authors Yan, Dong, Tan, Jia, Chen, Dong, Yuan, Liping, Huang, Zizhi, Zou, Dongfang, Peng, Dongmei, Song, Ling, Tao, Qiang, Tan, zhengde, Deng, Jiyong, Hu, Yunchu
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer Berlin Heidelberg 01.02.2024
Springer Nature B.V
Subjects
Biomedical and Life Sciences
Calorimetry
Ceramics
Composites
Cysteine
Density
Enthalpy
Flame retardants
Glass
Hardwoods
Heat release rate
Heat transfer
Hot pressing
Life Sciences
Machines
Manufacturing
Natural Materials
Original Article
Poplar
Powder
Processes
Scanning electron microscopy
Thermal decomposition
Wood Science & Technology
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Summary:A novel reactive flame retardant based on L-cysteines containing P, N and S flame retardant elements was synthesized, and using its good water solubility, different concentrations of flame retardant poplar wood powder were prepared, and using the hot pressing process method, flame retardant density boards were made and their flame retardancy was studied. The thermogravimetric infrared coupler (TG-FTIR) test and thermal cracking gas mass spectrometer (Py-GC–MS) test both revealed that the flame retardant modified the thermal decomposition pathway of the wood, forming many residues and producing only a small amount of combustible gas. The ultimate oxygen index (LOI) of poplar density board treated with 20% cysteine-based flame retardant was as high as 60.9%. Scanning electron microscopy (SEM) images revealed that the surface of the treated wood powder was rough and that the wood powder particles were interconnected by the flame retardant. This suggests that the flame-retardant molecules have a bridging effect on the inner structure of the density board. Moreover, the cone calorimetry (CONE) experiments showed that with the flame-retardant treatment, there was significant reduction of total heat release (THR) and heat release rate (HRR) of the density board. The outcomes demonstrated the excellent flame retardancy and catalytic carbon formation of the poplar density board treated with the flame retardant. These findings demonstrate the effectiveness of the cysteine-based flame retardant.
ISSN:0018-3768
1436-736X
DOI:10.1007/s00107-023-01984-x