Abstract
Color changes of four softwood and seven hardwood species during hygrothermal treatment were compared among species and kinetically evaluated. Treatment temperature ranged from 70 to 120 °C, and the durations were 5–150 h. Generally, the \(L^{*}\) (lightness) decreased and the total color differences \((\Delta E_{\text{ab}}^{*})\) increased irrespective of the treatment temperature. \(a^{*}\) and \(b^{*}\) (redness and yellowness) values varied spuriously based on the wood species. Kinetic analysis using the time–temperature superposition principle, which uses the whole data set, was successfully applied to the color changes. The apparent activation energies of the color changes calculated from \(\Delta E_{\text{ab}}^{*}\) were 24.3–40.8 kJ/mol for softwood and 32.3–61.3 kJ/mol for hardwood. The average apparent activation energy for hardwood was higher than for softwood. These values were lower than those calculated from other material properties. The obtained results will contribute to assess the color changes during the early stage of kiln drying and hygrothermal modification of wood.
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References
Bekhta P, Niemz P (2003) Effect of high temperature on the change in color, dimensional stability and mechanical properties of spruce wood. Holzforschung 57:539–546
Brischke C, Welzbacher CR, Brandt K, Rapp AO (2007) Quality control of thermally modified timber: interrelationship between heat treatment intensities and CIE L*a*b* color data on homogenized wood samples. Holzforschung 61:19–22
Ding HZ, Wang ZD (2007) Time–temperature superposition method for predicting the permanence of paper by extrapolating accelerated ageing data to ambient conditions. Cellulose 14:171–181
Esteves B, Pereira H (2009) Wood modification by heat treatment: a review. Bioresources 4:370–404
Esteves B, Marques AV, Domingos I, Pereira H (2008) Heat-induced colour changes of pine (Pinus pinaster) and eucalypt (Eucalyptus globulus) wood. Wood Sci Technol 42:369–384
Gillen KT, Celina M (2001) The wear-out approach for predicting the remaining lifetime of materials. Polym Degrad Stab 71:15–30
Gillen KT, Clough RL (1989) Time–temperature-dose rate superposition: a methodology for extrapolating accelerated radiation aging data to low dose rate conditions. Polym Degrad Stab 24:137–168
Goli G, Marcon B, Fioravanti M (2014) Poplar wood heat treatment: effect of air ventilation rate and initial moisture content on reaction kinetics, physical and mechanical properties. Wood Sci Technol 48:1303–1316
González-Peña MM, Hale MDC (2009a) Colour in thermally modified wood of beech, Norway spruce and Scots pine. Part 1: colour evolution and colour changes. Holzforschung 63:385–393
González-Peña MM, Hale MDC (2009b) Colour in thermally modified wood of beech, Norway spruce and Scots pine. Part 2: property predictions from colour changes. Holzforschung 63:394–401
González-Peña MM, Hale MD (2011) Rapid assessment of physical properties and chemical composition of thermally modified wood by mid-infrared spectroscopy. Wood Sci Technol 45:83–102
Hon DNS, Mineura N (2001) Color and discoloration. In: Hon DNS, Shiraishi N (eds) Wood and cellulosic chemistry. Marcel Dekker, New York, pp 385–442
JIS Z 8730 (2009) Colour specification-colour differences of object colours
JIS Z 8781-4 (2013) Colorimetry-Part 4: CIE 1976 L*a*b* Colour space
Johansson D, Morén T (2006) The potential of colour measurement for strength prediction of thermally treated wood. Holz Roh Werkst 64:104–110
Kohara J (1958a) Study on the old timber. Res Rep Fac Technol Chiba Univ 9(15):1–55 [in Japanese]
Kohara J (1958b) Study on the old timber. Res Rep Fac Technol Chiba Univ 9(16):23–65 [in Japanese]
Kübler H (1987) Growth stresses in trees and related wood properties. For Prod Abstr 10(3):61–119
Matsuo M, Yokoyama M, Umemura K, Gril J, Yano K, Kawai S (2010) Color changes in wood during heating: kinetic analysis by applying a time–temperature superposition method. Appl Phys A Mater 99:47–52
Matsuo M, Yokoyama M, Umemura K, Sugiyama J, Kawai S, Gril J, Kubodera S, Mitsutani T, Ozaki H, Sakamoto M, Imamura M (2011) Aging of wood: analysis of color changes during natural aging and heat treatment. Holzforschung 65:361–368
Matsuo M, Umemura K, Kawai S (2012) Kinetic analysis of color changes in cellulose during heat treatment. J Wood Sci 58:113–119
Matsuo M, Umemura K, Kawai S (2014) Kinetic analysis of color changes in keyaki (Zelkova serrata) and sugi (Cryptomeria japonica) wood during heat treatment. J Wood Sci 60:12–20
Menezzi CHS, Tomaselli I, Okino EYA, Teixeira DE, Santana MAE (2009) Thermal modification of consolidated oriented strandboards: effects on dimensional stability, mechanical properties, chemical composition and surface color. Eur J Wood Wood Prod 67:383–396
Möttönen V, Kärki T (2008) Color changes of birch wood during high-temperature drying. Dry Technol 26:1125–1128
Navi P, Sandberg D (2012) Heat treatment. Thermo-hydro-mechanical processing of wood. EPFL Press, Lausanne, pp 249–286
Okuyama T, Yamamoto H, Murase Y (1988) Quality improvement in small log of sugi by direct heating method. Wood Ind 43:359–363 [in Japanese with English summary]
Okuyama T, Yamamoto H, Kobayshi I (1990) Quality improvement in small log of sugi by direct heating method (2). Wood Ind 45:63–67 [in Japanese with English summary]
Stamm AJ (1956) Thermal degradation of wood and cellulose. Ind Eng Chem 48:413–417
Sundqvist B (2002) Color response of Scots pine (Pinus sylvestris), Norway spruce (Picea abies) and birch (Betula pubescens) subjected to heat treatment in capillary phase. Eur J Wood Wood Prod 60:106–114
Wise J, Gillen KT, Clough RL (1995) An ultrasensitive technique for testing the Arrhenius extrapolation assumption for thermally aged elastomers. Polym Degrad Stab 49:403–418
Xu C, Xing C, Pan H, Kamdem PD, Matuana LM, Jian W, Wang G (2016) Time–temperature superposition principle application to the hygrothermal discoloration of colored high-density polypropylene/wood composites. Polym Compos 37(4):1016–1020
Zou X, Uesaka T, Gurnagul N (1996) Prediction of paper permanence by accelerated aging II. Comparison of the predictions with natural aging results. Cellulose 3:243–267
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The authors are grateful to the late Professor Okuyama for his guidance with this study.
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Matsuo, M.U., Mitsui, K., Kobayashi, I. et al. Effect of hygrothermal treatment on wood properties: color changes and kinetic analysis using four softwood and seven hardwood species. Wood Sci Technol 50, 1145–1160 (2016). https://doi.org/10.1007/s00226-016-0833-1
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DOI: https://doi.org/10.1007/s00226-016-0833-1