A Critical Role for the Presence of Lignocellulosic Material in the Determination of Wood Buffering Capacity

REFERENCES

• Zbořil, J.; Pesci, P. Opinion of the European Economic and Social Committee on ‘Opportunities and Challenges for a More Competitive European Woodworking and Furniture Sector’ (Own-initiative Opinion); CCMI/088, Brussels, 2011.
   Google Scholar
• Mantau, U. Wood Resource Balance Results – Is There Enough Wood for Europe? In EUwood – Real Potential for Changes in Growth and Use of EU Forests. Final Report; Mantau U., Saal, U., Prins, K., Steierer, F., Lindner M., Verkerk, PJ, Eggers,J., Leek, N., Oldenburger, J., Asikainen, A., Anttila, P.; University of Hamburg, Centre of Wood Science; Hamburg, 2010; 19–34.
   Google Scholar
• Roffael, E.; Schütze, S. Reactivity of water extractives in oak fibres towards formaldehyde. European Journal of Wood and Wood Products 2017, 75, 275–276.
   Web of Science ®Google Scholar
• Hafizoğlu, H. Wood extractives of Pinus sylvestris L., Pinus nigra Arn., Pinus brutia Ten. with special reference to nonpolar components. Holzforschung 1983, 37, 321–326.
   Web of Science ®Google Scholar
• Ekman, R.; Holmbom, B. The chemistry of wood resin. In Pitch control, Wood Resin and Deresination; Black E.L., Allen L.H., Eds.; TAPPI; Atlanta, 2000; 37–76.
   Google Scholar
• Fernando, D.; Hafrén, J.; Gustafsson, J.; Daniel, G. Micromorphology and topochemistry of extractives in Scots pine and Norway spruce thermomechanical pulps: A cytochemical approach. Journal of Wood Science. 2008, 54, 134–142.
   Web of Science ®Google Scholar
• Roffael, E. Significance of wood extractives for wood bonding. Applied Microbiology and Biotechnology 2016, 100(4), 1589–1596.
   PubMed Web of Science ®Google Scholar
• Chen C.M. Effect of extractive removal on adhesion and wettability of some tropical woods. Forest Products Journal 1970, 20, 36–39.
   Google Scholar
• Campbell, A.; Kim, W.J.; Koch, P. Chemical variation in Lodgepole pine sapwood/heartwood, stem height, and variety. Wood and Fiber Science 1990, 22(1), 22–30.
   Web of Science ®Google Scholar
• Hernández, V. Radiata pine pH and buffering capacity: effect of age and location in the stem. MADERAS: Ciencia y Tecnología 2013, 15(1), 73–78.
   Web of Science ®Google Scholar
• Roffael, E.; Rauch, W. Extraktstoffe in Eiche und ihr Einfluß auf die Verleimbarkeit mit alkalischen Phenol-Formaldehydharzen. Holz als Roh- und Werkstoff 1974, 32(5), 182–187.
   Google Scholar
• Guevara, R.; Johns, W. Geographical and within-tree variation in heartwood pH of Pinus oocarpa Scheide from Honduras. The Malaysian Forester 1980, 13(4), 200–224.
   Google Scholar
• Irle, M.; Barbu, M. Wood-based panel technology. In: Wood-based Panels – An Introduction for Specialist; Thoemen H., Irle M., Sernek M., Eds.; Brunei University Press; London, 2010, 278.
   Google Scholar
• Ingruber, O. The behaviour of wood and wood constituents as acid-buffering systems. Pulp and Paper 1958, 59(11), 135–141.
   Google Scholar
• Klauditz, W. Zur biologisch-mechan-ischen Wirkung der Acetylgruppen im Festigungsgewebe der Laubhölzer. Holzforschung 1957, 11(2), 47–55.
   Google Scholar
• Packman, D. The acidity of wood. Holzforschung 1960, 14(6), 178–183.
   Google Scholar
• Frąckowiak I. Higieniczność Płyt Wiórowych z Różnych Gatunków Drewna. Las – drewno – ekologia, Poland, 1997 (in Polish).
   Google Scholar
• Xing, C.; Zhang, S.Y.; Deng, J. Effect of wood acidity and catalyst on UF resin gel time. Holzforschung 2004, 58(3), 408–412.
   Web of Science ®Google Scholar
• Roffael, E.; Rauch, W.; Bismarck, C. Formaldehydabgabe und Festigkeitsausbildung bei der Verleimung von Eichenspänen mit Harnstofformaldehydharzen. Holz als Roh- und Werkstoff 1975, 33, 271–275.
   Google Scholar
• Van Niekerk, J.; Pizzi, A. Characteristic industrial technology for exterior Eucalyptus particleboard. Holz als Roh- und Werkstoff 1994, 52,109–112.
   Google Scholar
• Martin, A. Wood Acidity in Radiata Pine and its Effect on Particle Boards (Bachelor of Science Thesis). The Australian National University, 1995.
   Google Scholar
• Holmbom, B. Extractives. In Analytical Methods in Wood Chemistry. Pulping, and Papermaking; Sjöström, E., Alén, R., Eds.; Springer-Verlag; Berlin, 1999; 125–148.
   Google Scholar
• Silvério, F.O.; Barbosa, L.C.A.; Fidêncio, P.H.; Cruz, M.P., Maltha, C.R.A.; Piló-Veloso, D. Evaluation of chemical composition of eucalyptus wood extracts after different storage times using principal component analysis. Journal of Wood Chemistry and Technology 2011, 31, 26–41.
   Web of Science ®Google Scholar
• Anäs, E.; Ekman, R.; Holmbom, B. Composition of nonpolar extractives in bark of Norway spruce and Scots pine. Journal of Wood Chemistry and Technology 1983, 3, 119–130.
   Web of Science ®Google Scholar
• Poncsak, S.; Kocaefe, D.; Simard, F.; Pichette, A. Evolution of extractive composition during thermal treatment of Jack pine. Journal of Wood Chemistry and Technology 2009, 29, 251–264.
   Web of Science ®Google Scholar
• Johns, W.; Niazi, K. Effect of pH and buffering capacity of wood on the gelation time and urea-formaldehyde resin. Wood and Fiber Science 1981, 12(4), 255–263.
   Google Scholar
• Harris, J.F.; Baker, A.J.; Conner, A.H.; Jeffries, T.W.; Minor, J.L.; Pettersen, R.C.; Scott, R.W.; Springer, E.L.; Wegner, T.H.; Zrebe, J.I. Two-Stage, dilute sulfuric acid hydrolysis of wood: An investigation of fundamentals, General Technical Report. FPL-45. Madison, WI: U.S. Department of Agriculture, Forest Service, Forest Products Laboratory; 1985.
   Google Scholar
• Jacobs, A.; Larsson, P.T.; Dahlman, O. Distribution of uronic acids in xylans from various species of soft- and hardwood as determined by MALDI mass spectrometry. Biomacromolecules 2001, 2, 979–990.
   PubMed Web of Science ®Google Scholar
• Butler, J.N. Ionic Equilibrium: A Mathematical Approach, Addison-Wesley Publishing Company Inc.: Reading, USA, 1964.
   Google Scholar