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09-03-2019 | Original

Mechanical behaviour of chemically modified Norway spruce (Picea abies L. Karst.): Experimental mechanical studies on spruce wood after methacrylation and in situ polymerization of styrene

Authors: Samuel Oluyinka Olaniran, Benjamin Michen, Diego F. Mora Mendez, Falk K. Wittel, Erik Valentine Bachtiar, Ingo Burgert, Markus Rüggeberg

Published in: Wood Science and Technology | Issue 2/2019

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Abstract

Chemical modification of wood mainly aims at improving dimensional stability, resistance to biodeterioration and surface degradation. In some cases, it is specifically targeted at adapting or improving mechanical performance. However, a general understanding of the effects of chemical modification on the mechanical properties of wood, which would facilitate more efficient modification strategies, is missing. Here, a combined experimental and simulation study is provided to gain a more general understanding of the mechanical behaviour of chemically modified wood. In the first part of this study, the mechanical properties of chemically modified Norway spruce are studied experimentally. In Mora Mendez et al. (Wood Sci Technol 2019), simulations of different types of chemical modifications will be presented using a multi-scale model and the outcome will be compared with the obtained experimental data. Chemical modification was based on a two-step modification process. The first step involved methacrylation of the OH-groups in the cell wall. In the second step, in situ polymerization of styrene was induced in the methacrylated samples, which resulted in a partial cell wall and lumen filling. Tensile stiffness and rolling shear stiffness were analysed for methacrylated and polymerized samples. Whereas only small changes in mechanical properties were found for methacrylated samples, the polymerization process led to pronounced increases in elastic modulus and shear stiffness because of weight percent gains of 60–95%. Yet, the specific stiffness was lowered, as the density increase was disproportionate to the stiffness increase. Moreover, a pronounced improvement in rolling shear modulus (G_RT) by a factor of 4.5 was obtained for the in situ polymerized specimen.

previous article Water potential gradient between sapwood and heartwood as a driving force in water accumulation in wetwood in conifers

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Akitsu H, Norimoto M, Morooka T, Rowell RM (1993) Effect of humidity on vibrational properties of chemically modified wood. Wood Fiber Sci 25:250–260

Alma M, Hafizo lu H, Maldas D (1996) Dimensional stability of several wood species treated with vinyl monomers and polyethylene glycol-1000. Int J Polym Mater 32:93–99CrossRef

Arcan M, Hashin Z, Voloshin A (1978) A method to produce uniform plane-stress states with applications to fiber-reinforced materials. Exp Mech 18:141–146CrossRef

Bachtiar EV, Sanabria SJ, Mittig JP, Niemz P (2017) Moisture-dependent elastic characteristics of walnut and cherry wood by means of mechanical and ultrasonic test incorporating three different ultrasound data evaluation techniques. Wood Sci Technol 51:47–67CrossRef

Bengtsson C (2001) Variation of moisture induced movements in Norway spruce (Picea abies). Ann For Sci 58:568–581CrossRef

Blaber J, Adair B, Antoniou A (2015) Ncorr: open-source 2D digital image correlation Matlab software. Exp Mech 55:1105–1122CrossRef

Bucur V (2006) Acoustics of wood. Springer series in wood science. Springer, Berlin

Burgert I, Frühmann K, Keckes J, Fratzl P, Stanzl-Tschegg SE (2003) Microtensile testing of wood fibers combined with video extensometry for efficient strain detection. Holzforschung 57:661–664CrossRef

Clausen CA (2012) Enhancing durability of wood-based composites with nanotechnology. General technical report FPL–GTR-218:8-12

Dahl KB, Malo K (2009) Linear shear properties of spruce softwood. Wood Sci Technol 43:499–525CrossRef

Devi RR, Ali I, Maji T (2003) Chemical modification of rubber wood with styrene in combination with a crosslinker: effect on dimensional stability and strength property. Bioresour Technol 88:185–188CrossRefPubMed

Dinwoodie J (1981) Timber, its nature and behaviour. Van Nostrand Reinhold Co 190:60–61

EN 12668-1 (2010) Non-destructive testing—characterization and verification of ultrasonic examination equipment—part 1: instruments. CEN European Committee for Standardization

Epmeier H, Kliger R (2005) Experimental study of material properties of modified Scots pine. Holz als Roh-und Werkstoff 63:430–436CrossRef

Esteves B, Nunes L, Pereira H (2011) Properties of furfurylated wood (Pinus pinaster). Eur J Wood Wood Prod 69:521–525CrossRef

Gérardin P (2016) New alternatives for wood preservation based on thermal and chemical modification of wood—a review. Ann For Sci 73:559–570CrossRef

Gonçalves R, Trinca AJ, Cerri DGP (2011) Comparison of elastic constants of wood determined by ultrasonic wave propagation and static compression testing. Wood Fiber Sci 43:64–75

Hansmann C, Deka M, Wimmer R, Gindl W (2006) Artificial weathering of wood surfaces modified by melamine formaldehyde resins. Holz als Roh-und werkstoff 64:198CrossRef

Hillis W (1984) High temperature and chemical effects on wood stability. Wood Sci Technol 18:281–293CrossRef

Homan WJ, Jorissen AJ (2004) Wood modification developments. Heron 49:360–369

Imamura H (1989) Contribution of extractives to wood characteristics. In: Natural products of woody plants. Springer, pp 843–860

Keplinger T, Cabane E, Chanana M, Hass P, Merk V, Gierlinger N, Burgert I (2015) A versatile strategy for grafting polymers to wood cell walls. Acta Biomater 11:256–263CrossRefPubMed

Keunecke D, Sonderegger W, Pereteanu K, Lüthi T, Niemz P (2007) Determination of Young’s and shear moduli of common yew and Norway spruce by means of ultrasonic waves. Wood Sci Technol 41:309CrossRef

Kim J-W, Harper DP, Taylor AM (2009) Effect of extractives on water sorption and durability of wood-plastic composites. Wood Fiber Sci 41:279–290

Kohlhauser C, Hellmich C (2013) Ultrasonic contact pulse transmission for elastic wave velocity and stiffness determination: influence of specimen geometry and porosity. Eng Struct 47:115–133CrossRef

Lande S, Eikenes M, Westin M, Schneider MH (2008) Furfurylation of wood: chemistry, properties, and commercialization. ACS Publications, New York

Lubarsky G, Davidson M, Bradley R (2004) Elastic modulus, oxidation depth and adhesion force of surface modified polystyrene studied by AFM and XPS. Surf Sci 558:135–144CrossRef

Militz H (1991) Improvements of stability and durability of Beechwood (Fagus sylvatica) by means of treatment with acetic anhydride. In: Proceedings of 22nd annual meeting international research group on wood preservation, working group 3. Preservatives and methods of treatment. Kyoto, Japan. Doc. no: IRG/WP/3645

Militz H (1993) Treatment of timber with water soluble dimethylol resins to improve their dimensional stability and durability. Wood Sci Technol 27:347–355CrossRef

Miyake K, Satomi N, Sasaki S (2006) Elastic modulus of polystyrene film from near surface to bulk measured by nanoindentation using atomic force microscopy. Appl Phys Lett 89:031925CrossRef

Mora Mendez DF, Olaniran SO, Rüggeberg M, Burgert I, Hermann HJ, Wittel FK (2019) Mechanical behavior of chemically modified Norway spruce: a generic hierarchical model for wood modifications. Wood Sci Technol. https://doi.org/10.1007/s00226-019-01082-3 CrossRef

Norimoto M, Gril J, Rowell RM (1992) Rheological properties of chemically modified wood: relationship between dimensional and creep stability. Wood Fiber Sci 24:25–35

Ozyhar T, Hering S, Niemz P (2013) Moisture-dependent orthotropic tension-compression asymmetry of wood. Holzforschung 67:395–404

Pugh TL, Heller W (1957) Density of polystyrene and polyvinyltoluene latex particles. J Colloid Sci 12:173–180CrossRef

Rafsanjani A, Lanvermann C, Niemz P, Carmeliet J, Derome D (2013) Multiscale analysis of free swelling of Norway spruce. Compos A Appl Sci Manuf 54:70–78CrossRef

Ramage MH et al (2017) The wood from the trees: the use of timber in construction. Renew Sustain Energy Rev 68:333–359CrossRef

Rowell RM (1983) Chemical modification of wood. Prod Abstr Rev Artic 6:362–382

Rowell RM (1996) Physical and mechanical properties of chemically modified wood. Chem Modif Lignocellul Mater 1:295–310

Singleton R, DeBell DS, Gartner BL (2007) Effect of extraction on wood density of western hemlock (Tsuga heterophylla (Raf.) Sarg.). Wood Fiber Sci 35:363–369

Socrates G (2001) Infrared and Raman characteristic group frequencies: tables and charts. Wiley, Hoboken

Xie Y, Krause A, Militz H, Turkulin H, Richter K, Mai C (2007) Effect of treatments with 1,3-dimethylol-4,5-dihydroxy-ethyleneurea (DMDHEU) on the tensile properties of wood. Holzforschung 61:43–50CrossRef

Xie Y, Fu Q, Wang Q, Xiao Z, Militz H (2013) Effects of chemical modification on the mechanical properties of wood. Eur J Wood Wood Prod 71:401–416CrossRef

Yildiz ÜC, Yildiz S, Gezer ED (2005) Mechanical properties and decay resistance of wood–polymer composites prepared from fast growing species in Turkey. Bioresour Technol 96:1003–1011CrossRefPubMed

Zaoui A (2002) Continuum micromechanics: survey. J Eng Mech 128:808–816CrossRef

Title: Mechanical behaviour of chemically modified Norway spruce (Picea abies L. Karst.): Experimental mechanical studies on spruce wood after methacrylation and in situ polymerization of styrene
Authors: Samuel Oluyinka Olaniran
Benjamin Michen
Diego F. Mora Mendez
Falk K. Wittel
Erik Valentine Bachtiar
Ingo Burgert
Markus Rüggeberg
Publication date: 09-03-2019
Publisher: Springer Berlin Heidelberg
Published in: Wood Science and Technology / Issue 2/2019
Print ISSN: 0043-7719
Electronic ISSN: 1432-5225
DOI: https://doi.org/10.1007/s00226-019-01080-5

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