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A wooden object that has survived in a wet environment is characterised by water saturation and is called waterlogged wood. The subject of the study was elm piles, dating back to the 10th and11th century, excavated from Lednica lake archaeological site. Wooden piles showed a high degree of degradation. This was evidenced by their spongy and fragile structure. As a result of the biotic and abiotic degradation of the wood cell wall, a significant change in its chemical composition was observed. The weakening of the wood structure and its increase in porosity were as a result of cellulose degradation. The archaeological wood conservation method used until now is polyethylene glycol (PEG). However, this method has some drawbacks such as highdensity wood after treatment, the colour of the wood and it is a long-term process. It has already been found that alkoxysilanes are potential alternatives to the commonly used PEG. The purpose of the study was to determine the optimum concentration of methyltrimethoxysilane (MTMOS) for the medieval elm wood conservation. The general aim of the study was to develop an effective waterlogged wood dimensional stabilization through its silanization with MTMOS. After long-term dehydration (replacement of water for ethanol, during an ethanol bath) wood samples were saturated with MTMOS solutions of various concentrations. Wood samples were treated through the oscillating vacuum-pressure method. Dimensional stabilization of the sililated wood was estimated through the anti-shrink efficiency (ASE) calculation. The ASE value for PEG and MTMOS treated wood samples was 88.6% and 96.8% respectively. It was found that an ethanol solution of 20% MTMOS is the optimum concentration for waterlogged elm wood dimensional stabilization treatment (ASE = 94.1 %). The other advantage of this method includes a short impregnation time and low density of the preserved wood.
Słowa kluczowe
Rocznik
Tom
Strony
169--179
Opis fizyczny
Bibliogr. 28 poz., rys., tab.
Twórcy
autor
- Poznań University of Life Sciences, Faculty of Wood Technology, Poznań, Poland
autor
- Poznań University of Life Sciences, Faculty of Wood Technology, Poznań, Poland
autor
- Poznań University of Life Sciences, Faculty of Wood Technology, Poznań, Poland
Bibliografia
- Ambrose W.R. [1990]: Application of freeze-drying to archaeological wood. In: Rowell R.M., Barbour R.J. (eds.), Archaeological Wood: Properties, Chemistry and Preservation. Advances in Chemistry, Series 225, American Chemical Society, Washington DC: 235--263
- Babiński L. [2012]: Research on dimensional stability in waterlogged archaeological wood dried in non-cooled vacuum chamber connected to a laboratory freeze-dryer. Drewno 55 [187]: 5-19
- Babiński L., Poskrobko J. [2005]: Badanie wchłonięcia poliglikoli etylenowych do mokrego drewna archeologicznego. In: Prądzyński W. (ed.), Badania i konserwacja drewna archeologicznego: 93-103
- Broda M., Mazela B. [2017]: Application of methyltrimethoxysilane to increase dimensional stability of waterlogged wood. Journal of Cultural Heritage 25: 149-156
- Browning B.L. [1967]: The chemistry of wood. Interscience Publisher, USA
- Cook C., Grattan D.W. [1985]: A practical comparative study of treatments for waterlogged wood: part III: pretreatment solutions for freeze drying. Waterlogged wood: study and conservation. Proceedings of: the 2nd ICOM Waterlogged Wood Working Group Conference, Grenoble
- Grattan D.W. [1987]: Waterlogged wood. In: Pearson C. (ed.), Conservation of marine archeological objects. Butterworth, Boston: 55-67
- Hedges J. [1990]: The chemistry of archeological wood. In: Rowell R., Barbour R.J. (eds.), Archeological wood properties, chemistry and preservation. Advances in Chemistry Series 225. Washington
- Hill C.A.S., Farahani M.R.M., Hale M.D.C. [2004]: The use of organo alkoxysilane coupling agents for wood preservation. Holzforschung, 58: 316-325
- Hoffmann P. [1981]: Chemical wood analysis as a means of characterizing archeological wood. Proceedings of: the ICOM Waterlogged Wood Working Group Conference, Ottawa: 73-83
- Koch G., Melcher E., Lenz M.T., Bauch J. [2018]: Biological and topochemical studies on the resistance of excavated oak piles (Quercus sp.) from a historical bridge in Bavaria. Holzforschung 72 [2]: 133-141
- Jensen P., Schnell U. [2005]: The implications of using low molecular weight PEG for impregnation of waterlogged archaeological wood prior to freeze drying. In: Hoffmann P., Stratkvern K., Spriggs J.A., Gregory D. (eds.), Proceedings of the 9th ICOM Group on Wet Organic Archaeological Materials Conference
- Jensen P., Gregory D.J. [2006]: Selected physical parameters to characterize the state of preservation of waterlogged archaeological wood: a practical guide for their determination. Journal of Archaeological Science 33: 551-559
- Nilsson T., Bjordal Ch. [2002]: Microbial degradation on waterlogged archaeological wood. Proceedings of: IAWS 2002 Beijing Conference
- Olek W., Majka J., Stempin A., Sikora M., Zborowska M. [2016]: Hygroscopic properties of PEG treated archaeological wood from the rampart of the 10th century stronghold as exposed in the Archaeological Reserve Genius loci in Poznań (Poland). Journal of Cultural Heritage 18: 299-305
- Pizzo B., Giachi G., Fiorentino L. [2010]: Evaluation of the applicability of conventional methods for the chemical characterization of waterlogged archaeological wood. Archaeometry 52 [4]: 656-667
- Sakai H. [2001]: Analysis of degradation observed on ancient wooden objects buried underground. IRG/WP 01-10403
- Sebe G., Brook M.A. [2001]: Hydrophobization of wood surfaces: covalent grafting silicone polymers. Wood Science and Technology 35: 269-282
- Smith C.W., Hamilton D.L. [2001]: Treatment of waterlogged wood using hydrolyzable multi-functional alkoxysilane polymers. Proceedings of: the 8th ICOM group on Wet Organic Archaeological Materials conference, Stockholm: 614-615
- Stamm A.J. [1956]: Dimensional stabilization of wood with carbowaxes. Forest Products Journal 6 [5]: 201-204
- Stamm A.J. [1959]: Effect of polyethylene glycol on the dimensional stability of wood. Forest Products Journal 9 [10]: 375-381
- Tejedor C.C. [2010]: Re-conservation of wood from the seventeenth-century Swedish warship the vasa with alkoxysilanes: A Re-treatment Study Applying Thermosetting Elastomers
- Tshabalala M.A., Gangstad J.E. [2003]: Accelerated weathering of wood surfaces coated with multifunctional alkoxysilanes by sol-gel deposition. Journal of Coatings Technology. DOI: https://doi.org/10.1007/BF02730098
- Unger A., Schniewind A.P., Unger W. [2001]: Conservation of wood artifacts. A handbook. Springer-Verlag Berlin Heidelberg
- Ważny J. [1976]: Deterioration of ancient wood in Biskupin archeological excavations. Material und Organismen (Berlin) 3: 53-62
- Zborowska M., Spek- Dźwigała A., Waliszewska B., Prądzyński W. [2004]: Ocena stopnia degradacji drewnianych obiektów archeologicznych z najcenniejszych znalezisk wielkopolskich (The estimation of degradation of wooden archeological objectives from most valuable excavation from wielkopolska). Acta Scientiarum Polonorum Silvarum Colendarum Ratio et Industria Lignaria 3 [2]: 139-151
- List of standards
- TAPPI (US technical association of pulp and paper industry) 2006 Acid insoluble lignin in wood and pulp T 222 om-06
- TAPPI (US technical association of pulp and paper industry) 2007a Solvent extractives of wood and pulp T 204 cm-07
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).
Typ dokumentu
Bibliografia
Identyfikator YADDA
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