A comparative study on hydrophobic properties of wood functionalized by phthalic and acetic anhydrides

Document Type : Complete scientific research article

Authors

1 M.Sc., Dept. of Wood and Paper Science & Technology, Faculty of Natural Resources, University of Tehran, Karaj, Iran

2 Associate Prof., Dept. of Wood and Paper Science & Technology, Faculty of Natural Resources, University of Tehran, Karaj, Iran

3 University of Tehran

4 Dept. of Wood and Paper Science & Technology, Faculty of Natural Resources, University of Tehran, Karaj, Iran

Abstract

Background and objectives: Hygroscopic nature of wood is one of the limiting factors for some outdoor applications. Coating, impregnation with various hydrophobic chemicals or modification methods can be applied to protect the wood against moisture absorption. In this study, the effect of chemical modification of wood by substituting hydroxyl groups with long and cyclic functional group (phthalate) and short group (acetyl) on its hygroscopic properties was investigated.
Materials and methods: Sapwood specimens of poplar (Populus deltoides) and Norway spruce (Picea abies) with 48 mm in diameter and 5 mm in thickness were cut. The specimens were extracted for 8 hours prior to modification using acetone/ethanol (2:1, v/v) solution. The specimens were then pressure treated with acetic anhydride and phthalic anhydride at 120 °C for 1, 2, 4 and 24 hours. After modification, the specimens were first washed with acetone for 48 hours and then washed with distilled water for 48 hours. After leaching, the specimens were dried in an oven at 103 ±2 °C for 24 h and weighed. Weight percent gain (WPG), physical properties of the modified wood including reduced equilibrium moisture content (EMC R), moisture exclusion efficiency (MEE) and wettability by Sessile Drop method were measured and the chemical changes were also evaluated by infrared spectroscopy test (ATR-FTIR).
Results: ATR-FTIR studies showed that the peak observed at 1732-1746 cm-1 which is related to the stretching vibration of carbonyl group (C=O) confirms the formation of ester bonds within both types of modified woods. The results showed that modification with acetic anhydride in comparison with phthalic anhydride at the same reaction time led to a higher WPG and lower MEE. Less WPG obtained by modification with phthalic anhydride can be due to the larger size and more non-polarity of the phthalate group compared to the acetyl group, as well as the hydrolysis of the ester bond between the phthalate and hydroxyl groups caused by leaching. However, there was no difference between the anti-moisture exclusion efficiencies of the woods modified by two types of anhydrides at the same WPG. In the acetylation process, modification of Norway spruce was more successful than that of poplar, whereas the wood species showed no difference in the modification with phthalic anhydride. The results of the wettability test showed that the contact angle of the Norway spruce increased after modification by both types of the anhydrides. However, in poplar wood, only the specimen modified by phthalic anhydride at high WPG had a higher contact angle than the control specimen. Results also showed that compared to the acetylation process, WPG of the wood modified by phthalic anhydride was less affected by increasing the reaction time. This may be due to the lower reactivity of the phthalic group with wood compared to the acetyl group.
Conclusion: There was no difference between the anti-moisture exclusion efficiencies of woods modified by short-chain anhydride (acetic anhydride) and the cyclic anhydride (phthalic anhydride) at the same WPG, which indicates that the type of anhydride does not affect this physical property of wood. Our results showed that wettability of the modified woods can be a function of other factors such as surface quality and permeability in addition to the amount of hydroxyl group substitution.

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References

 
1.Beck, G., Thybring, E.E., and Thygesen, L.G. 2018. Brown-rot fungal degradation and de-acetylation of acetylated wood. International Biodeterioration and Biodegradation. 135: 62-70.
2.Bodirlau, R., Teaca, C.A., and Spiridon, I. 2008. Chemical modification of beech wood: Effect on thermal stability. BioResources. 3: 3. 789-800.
3.Çetin, N.S., Özmen, N., and Birinci, E. 2011. Acetylation of wood with various catalysts. J. of Wood Chemistry and technology. 31: 2. 142-153.
4.Chang, H.T., and Chang, S.T. 2002. Moisture excluding efficiency and dimensional stability of wood improved by acylation. Bioresource Technology. 85: 2. 201-204.
5.Hill C.A.S. 2006. Wood modification-chemical, thermal and other processes. John Wiley and Sons Ltd, West Sussex, UK. 239p.
6.Huang, X., Kocaefe, D., Kocaefe, Y., and Pichette, A. 2018. Combined effect of acetylation and heat treatment on the physical, mechanical and biological behavior of jack pine (Pinus banksiana) wood. European J. of Wood and Wood Products. 76: 2. 525-540.
7.Jebrane, M., Pichavant, F., and Sèbe, G. 2011. A comparative study on the acetylation of wood by reaction with vinyl acetate and acetic anhydride. Carbohydrate Polymers. 83: 2. 339-345.‏
8.Moghaddam, M.S., Wålinder, M.E., Claesson, P.M., and Swerin, A. 2016. Wettability and swelling of acetylated and furfurylated wood analyzed by multicycle Wilhelmy plate method. Holzforschung. 70: 1. 69-77.
9.Mohebby, B. 2010. Application of ATR infrared spectroscopy in wood acetylation. J. of Agricultural Science and Technology. 10: 253-259.
10.Papadopoulos, A.N., Hill, C.A.S., and Gkaraveli, A. 2003. Determination of surface area and pore volume of holocellulose and chemically modified wood flour using the nitrogen adsorption technique. Holz als Roh-und Werkstoff. 61: 6. 453-456.
11.Passarini, L., Zelinka, S.L., Glass, S.V., and Hunt, C.G. 2017. Effect of weight percent gain and experimental method on fiber saturation point of acetylated wood determined by differential scanning calorimetry. Wood Science and Technology. 51: 6. 1291-1305.
12.Popescu, C.M., Hill, C.A.S., Curling, S., Ormondroyd, G., and Xie, Y. 2014.The water vapour sorption behaviour of acetylated birch wood: how acetylation affects the sorption isotherm and accessible hydroxyl content. J. of Materials Science. 49: 2362–2371.
13.Ramsden, M.J., Blake, F.S.R., and Fey, N.J. 1997. The effect of acetylation on the mechanical properties, hydrophobicity and dimensional stability of Pinus sylvestris. Wood Science and Technology. 31: 2. 97-104.
14.Rautkari, L., Hill, C.A.S., Curling, S., Jalaludin, Z., and Ormondroyd, G. 2013. What is the role of the accessibility of wood hydroxyl groups in controlling moisture content. J. of Material Science. 48: 6352-6356.
15.Rowell, R.M. 2014. Acetylation of wood–A review. International J. of Lignocellulosic Products. 1: 1. 1-27.
16.Tarmian, A. 2017. Effect of species on the hydroxyl accessibility of wood: results obtained by deuterium exchange. Forest and Wood Products. 70: 2. 353-360.(In Persian)
17.Thybring, E.E., Piqueras, S., Tarmian, A., and Burget, I. 2020. Water accessibility to hydroxyls confined in solid wood cell walls. Cellulose. https:// doi.org/ 10.1007/ s10570-020-03182-x
Journal of Wood and Forest Science and Technology
Volume 27, Issue 2
September 2020
Pages 115-130

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