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Wood Science and Technology

21.04.2024 | Original

Plant cell wall reconstruction towards enhancing moisture stability and toughness by assembling delignified wood with alkali lignin

verfasst von: Feng Gu, Xiuxue Niu, Daquan Zhang, Zhaosheng Cai, Wangxia Wang, Junlong Song, Yongcan Jin, Huining Xiao

Erschienen in: Wood Science and Technology

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Abstract

Developing a moisture-stable structural material with high toughness is essential for improving the stability of packaging and building materials. Wood is a pervasive structural material with naturally good mechanical properties. However, insufficient moisture stability and toughness compromises its safety and structural requirements. Herein, we constructed a moisture-stable wood veneer with high toughness by assembling the choline chloride-ethanolamine delignified wood with alkali lignin, followed by hot-pressing to densify the material. Lignin can be assembled into the microchannel of the delignified wood as a filler and binder for reducing molecular transportation and increasing internal bonding. The enhanced tensile strength (582.0 MPa) and strain (3.6%) are accompanied by a significant increase in the toughness to 11.1 MJ/m³, which is 37 times higher than that of natural wood. The excellent mechanical property can be preserved to a large extent after retaining in tropic moisture conditions (38 °C, 90% RH) with retention of 66.2% and 60.8% for tensile strength and toughness, respectively. A stable water contact angle on the surface and limited water adsorption of reconstructed wood indicate a lowered water infiltration velocity, suggesting highly improved moisture stability as needed for structural materials.

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Titel: Plant cell wall reconstruction towards enhancing moisture stability and toughness by assembling delignified wood with alkali lignin
verfasst von: Feng Gu
Xiuxue Niu
Daquan Zhang
Zhaosheng Cai
Wangxia Wang
Junlong Song
Yongcan Jin
Huining Xiao
Publikationsdatum: 21.04.2024
Verlag: Springer Berlin Heidelberg
Erschienen in: Wood Science and Technology
Print ISSN: 0043-7719
Elektronische ISSN: 1432-5225
DOI: https://doi.org/10.1007/s00226-024-01552-3