Effects of densification on untreated and nano-aluminum-oxide impregnated poplar wood

Hamid R. Taghiyari; Ghonche Rassam; Kazem Ahmadi-DavazdahEmam

doi:10.1007/s11676-016-0321-3

Journal of Forestry Research ›› 2016, Vol. 28 ›› Issue (2) : 403 -410. DOI: 10.1007/s11676-016-0321-3

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Effects of densification on untreated and nano-aluminum-oxide impregnated poplar wood

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Abstract

Effects of densification of poplar wood (Populus nigra) impregnated with nano-aluminum oxide (NA) and pre-treated with water vapor for 4 and 6 h were investigated in the present study. Physical and mechanical properties of treated poplar wood were measured according to the ASTM D-143 standard specifications, and then compared with the untreated specimens. Results showed significant improvement in all properties as a result of densification. A 4-h vapor pre-treatment improved effects on both physical and mechanical properties. When the duration of vapor-treatment increased to 6 h, wood polymers degraded to the extent that the improvements due to the vapor pre-treatment decreased substantially, though the final results were still significant improvements compared with the control specimens. High thermal conductivity coefficient of NA slightly but not significantly improved properties. Due to the high spring-back after 15 days, densified poplar is not recommended for applications in which densified wood will be exposed for long periods to high humidity or to direct water.

Keywords

Wood modification / Impregnation / Poplar wood / Nano-suspension / Nano-aluminum oxide / Modification of wood

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Hamid R. Taghiyari, Ghonche Rassam, Kazem Ahmadi-DavazdahEmam. Effects of densification on untreated and nano-aluminum-oxide impregnated poplar wood. Journal of Forestry Research, 2016, 28(2): 403-410 DOI:10.1007/s11676-016-0321-3

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References

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[1]	Ada R. Cluster analysis and adaptation study for safflower genotypes. Bulg J Agric Sci, 2013, 19(1): 103-109.

[2]	Chaiyo K, Rattanadecho P. Numerical analysis of heat-mass transport and pressure build-up in 1D unsaturated porous medium subjected to a combined microwave and vacuum system. Drying Technol, 2013, 31(6): 684-697.

[3]	Fernandez-Puratich H, Oliver-Villanueva JV. Quantification of biomass and energetic value of young natural regenerated stands of Quercus ilex under Mediterranean conditions. BOSQUE, 2014, 35(1): 65-74.

[4]	Figueroa M, Bustos C, Dechent P, Reyes L, Cloutier A, Giuliano M. Analysis of rheological and thermo-hygro-mechanical behaviour of stress-laminated timber bridge deck in variable environmental conditions. Maderas, 2012, 14: 303-319.

[5]	Goli G, Cremonini C, Negro F, Zanuttini R, Fioravanti M. Physical-mechanical properties and bonding quality of heat treated poplar (I-214) and ceiba plywood. iForest J, 2014

[6]	Hill C (2006) Wood modification chemical, thermal and other processes. Wiley, New York, p. 239. ISBN: 0-470-02172-1

[7]	Krewski D, Yokel RA, Nieboer E, Borchelt D, Cohen J, Harry J, Kacew S Human health risk assessment for aluminium, aluminium oxide, and aluminium hydroxide. J Toxicol Environ Health B, 2007, 10: 1-269.

[8]	Maresi G, Oliveira Longa CM, Turchetti T. Brown rot on nuts of Castanea sativa Mill: an emerging disease and its causal agent. iForest, 2013, 6: 294-301.

[9]	Miri Tari SM, Habibzadeh S, Taghiyari HR. Effects of drying schedules on physical and mechanical properties in Paulownia wood. Drying Technol, 2015, 33: 1981-1990.

[10]	Oltean L, Teischinger A, Hansmann C. Influence of temperature on cracking and mechanical properties of wood during wood drying – A review. BioResources, 2007, 2(4): 789-811.

[11]	Oltean L, Teischinger A, Hansmann C. Influence of low and moderate temperature kiln drying schedules on specific mechanical properties of norway spruce wood. Eur J Wood Wood Prod, 2011, 69: 451-457.

[12]	Rassam Gh, Ghofrani M, Taghiyari HR, Jamnani B, Khajeh MA. Mechanical performance and dimensional stability of nano-silver impregnated densified spruce wood. Eur J Wood Wood Prod, 2012, 70(5): 595-600.

[13]	Schmidt O. Wood and tree fungi: biology, damage, protection, and use, 2006, Berlin: Springer-Verlag 334

[14]	Taghiyari HR. Effects of heat-treatment on permeability of untreated and nanosilver-impregnated native hardwoods. Maderas, 2013, 15(2): 183-194.

[15]	Taghiyari HR, Bibalan OF. Effect of copper nanoparticles on permeability, physical, and mechanical properties of particleboard. Eur J Wood Wood Prod, 2013, 71(1): 69-77.

[16]	Taghiyari HR, Moradi Malek M. Effect of heat treatment on longitudinal gas and liquid permeability of circular and square-shaped native hardwood specimens. Heat Mass Transf, 2014, 50(8): 1125-1136.

[17]	Taghiyari HR, Mobini K, Sarvari Samadi Y, Doosti Z, Karimi F, Asghari M, Jahangiri A, Nouri P. Effects of nano-wollastonite on thermal conductivity coefficient of medium-density fiberboard. J Mol Nanotechnol, 2013, 2: 1.

[18]	Taghiyari HR, Enayati A, Gholamiyan H. Effects of nano-silver impregnation on brittleness, physical and mechanical properties of heat-treated hardwoods. Wood Sci Technol, 2013, 47(3): 467-480.

[19]	Welzbacher CR, Sehsener J, Rapp AO, Haller P. Thermo-mechanical densification combined with thermal modification of Norway spruce (Picea abies Karst) in industrial scale-dimensional stability and durability aspects. Holz Roh Werkst, 2008, 66: 39-49.