Combined effects of multi-interfacial furfurylation and densification on mechanical-physical performances of fast-growing poplar wood

Upgrading low-quality wood with less consumption of modifier is demanded in sustainable development of wood industry. In this study, multi-interfacial furfurylation combined with densification was proposed to improve performances of wood. Different from traditional furfurylation, the multi-interfaci...

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Veröffentlicht in:	Journal of materials science 2022-08, Vol.57 (32), p.15340-15353
Hauptverfasser:	Yang, Tiantian, Mei, Changtong, Ma, Erni
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Sprache:	eng
Schlagworte:	Alcohol Analysis Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Coatings Composites & Nanocomposites Crack propagation Crystallography and Scattering Methods Densification Density Flexural strength Forestry Furfuryl alcohol Hydrophobicity Impact strength Industrial development Interfaces Materials Science Mechanical properties Moisture effects Molecular weight Nanocomposites Physical properties Polymer Sciences Poplar Reduction Solid Mechanics Sorption Stress concentration Sustainable development VOCs Volatile organic compounds Water absorption Water chemistry Wettability
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creator	Yang, Tiantian Mei, Changtong Ma, Erni
description	Upgrading low-quality wood with less consumption of modifier is demanded in sustainable development of wood industry. In this study, multi-interfacial furfurylation combined with densification was proposed to improve performances of wood. Different from traditional furfurylation, the multi-interfacial furfurylation comprised internal impregnation with 10% concentration furfuryl alcohol (FA) and surface coating with reused FA. After combined treatments, FA polymerized on wood surface, and also penetrated into cell lumina and cell walls. Some cell walls became closer and almost attached together. Wood mass increased by 12.6% and density reached 860 kg m −3 . The set recovery of densified wood decreased by over 92% due to multi-interfacial furfurylation. On account of density increase and multi-interfacial interactions among FA from wood surface to inner parts principally, the mechanical properties were significantly improved with over 260% increase of flexural strength and 50% enhancement of impact toughness. Physical properties were improved indicated by reduction of surface wettability, dynamic moisture sorption and water absorption mainly due to hydrophobicity increase, accessible sorption site decrease, water-path block and accommodation reduction for water molecules. The results can help facilitate better application of low-quality wood for building more efficient and environmentally friendly material industry. Graphical Abstract
doi_str_mv	10.1007/s10853-022-07581-2
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Physical properties were improved indicated by reduction of surface wettability, dynamic moisture sorption and water absorption mainly due to hydrophobicity increase, accessible sorption site decrease, water-path block and accommodation reduction for water molecules. The results can help facilitate better application of low-quality wood for building more efficient and environmentally friendly material industry. 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In this study, multi-interfacial furfurylation combined with densification was proposed to improve performances of wood. Different from traditional furfurylation, the multi-interfacial furfurylation comprised internal impregnation with 10% concentration furfuryl alcohol (FA) and surface coating with reused FA. After combined treatments, FA polymerized on wood surface, and also penetrated into cell lumina and cell walls. Some cell walls became closer and almost attached together. Wood mass increased by 12.6% and density reached 860 kg m −3 . The set recovery of densified wood decreased by over 92% due to multi-interfacial furfurylation. On account of density increase and multi-interfacial interactions among FA from wood surface to inner parts principally, the mechanical properties were significantly improved with over 260% increase of flexural strength and 50% enhancement of impact toughness. Physical properties were improved indicated by reduction of surface wettability, dynamic moisture sorption and water absorption mainly due to hydrophobicity increase, accessible sorption site decrease, water-path block and accommodation reduction for water molecules. The results can help facilitate better application of low-quality wood for building more efficient and environmentally friendly material industry. 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subjects	Alcohol Analysis Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Coatings Composites & Nanocomposites Crack propagation Crystallography and Scattering Methods Densification Density Flexural strength Forestry Furfuryl alcohol Hydrophobicity Impact strength Industrial development Interfaces Materials Science Mechanical properties Moisture effects Molecular weight Nanocomposites Physical properties Polymer Sciences Poplar Reduction Solid Mechanics Sorption Stress concentration Sustainable development VOCs Volatile organic compounds Water absorption Water chemistry Wettability
title	Combined effects of multi-interfacial furfurylation and densification on mechanical-physical performances of fast-growing poplar wood
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