Influence of environmental factors on the surface condition of thermally modified ash wood in polyvinyl acetate adhesive joints

Adrian Kindzera, Bogdan Kshyvetskyi, Andrii Spirochkin, Yurii Lakyda, Denys Zavialov
Abstract

The aim of this work was to study polyvinyl acetate adhesive joints of “thermally modified ash/pine wood” concerning changes in the surface condition of thermally modified ash wood (correlated with changes in the strength of the samples) under prolonged exposure to external factors. Test samples of adhesive joints were placed on a test rack for external exposure. Every three months, they were removed to record destructive changes in the thermally modified wood surface using scanning electron microscopy, assess changes in wettability and the duration of water droplet penetration into the structure (by measuring changes in contact angles over time), and determine changes in the strength of the adhesive joints. It was established that photochemical damage to thermally modified ash wood is the “trigger mechanism” for its further degradation changes. Samples exposed during summer periods exhibited more pronounced destructive changes in the thermally modified surface and a significant decrease in the strength of adhesive joints (from 6.56 MPa to 6.05 MPa after the first cycle and from 5.93 MPa to 5.62 MPa after the second cycle). The study showed that due to a cascade of destructive mechanisms, the structure of thermally modified ash wood, after 24 months of exposure to natural conditions, sustained damage to a depth of 0.05-0.2 mm (while the strength of the adhesive joints decreased from 7.12 MPa to 5.13 MPa), the surface became more hydrophilic, which led to a reduction in the time required for water penetration into its structure. Accordingly, the contact angle on such the surface reached θ = 17° after 480 seconds, while on the surface of thermally modified ash wood, which was not exposed to natural factors, a similar value was reached only after 570 s

Keywords

external factors, temperature-humidity loads, solar radiation, scanning electron microscopy, destructive changes, contact angle, water droplet penetration

Suggested citation
Kindzera, A., Kshyvetskyi, B., Spirochkin, A., Lakyda, Yu., & Zavialov, D. (2025). Influence of environmental factors on the surface condition of thermally modified ash wood in polyvinyl acetate adhesive joints. Ukrainian Journal of Forest and Wood Science, 16(3), 26-39. https://doi.org/10.31548/forest/3.2025.26
References
  1. DSTU EN 205:2014. (2014). Adhesives for glueing wood which is not subjected to power loads. A method for determining the strength of a lap joint during longitudinal shear tension. Retrieved from https://online.budstandart.com/ua/catalog/doc-page.html?id_doc=73788.
  2. EN 927-3:2006. (2006). Paints and varnishes  coating materials and coating systems for exterior wood. Retrieved from https://store.uni.com/en-927-3-2006.
  3. Gaff, M., Kubovský, I., Sikora, A., Kačíková, D., Li, H., Kubovský, M., & Kačík, F. (2023). Impact of thermal modification on color and chemical changes of African padauk, merbau, mahogany, and iroko wood species. Reviews on Advanced Materials Science, 62(1), article number 20220277. doi: 10.1515/rams-2022-0277.
  4. Godinho, D., Araújo, S.d.O., Quilhó, T., Diamantino, T., & Gominho, J. (2021). Thermally modified wood exposed to different weathering conditions: A review. Forests, 12, article number 1400. doi: 10.3390/f12101400.
  5. Horbachova, O., Mazurchuk, S., Lomaha, V., Buiskykh, N., Matviichuk, A., & Marchenko, N. (2025). Identifying patterns in the resistance of thermally modified ash wood to weathering. Eastern-European Journal of Enterprise Technologies, 1(12(133)), 6-15. doi: 10.15587/1729-4061.2025.322368.
  6. Jones, D., & Sandberg, D. (2020). A review of wood modification globally – updated findings from COST FP1407. Interdisciplinary Perspectives on the Built Environment, 1, 1-31. doi: 10.37947/ipbe.2020.vol1.1.
  7. Kačík, F., Výbohová, E., Jurczyková, T., Eštoková, A., Kmeťová, E., & Kačíková, D. (2025). Impact of thermal treatment and aging on lignin properties in spruce wood: Pathways to value-added applications. Polymers, 17, article number 238. doi: 10.3390/polym17020238.
  8. Kshyvetskyy, B., Kindzera, D., Sokolovskyy, Ya., Somar, H., & Sokolovskyi, I. (2023). Prediction of the strength of oakwood adhesive joints bonded with thermoplastic polyvinyl acetate adhesives. Chemistry & Chemical Technology, 17(1), 110-117. doi: 10.23939/chcht17.01.110.
  9. Kshyvetskyy, B., Kindzera, D., Sokolovskyi, I., Storozhuk, V., Mayevska, O., Somar H., & Kindzera, A. (2024). Features of the formation of cohesive and adhesive strength by non-structured and structured polyvinyl acetate films during wood gluing. Voprosy Khimii i Khimicheskoi Tekhnologii, 3, 89-97. doi: 10.32434/0321-4095-2024-154-3-89-97.
  10. Lunguleasa, A., & Spirchez, C. (2025). Influence of thermal treatment on properties of ash wood. Forests, 16, article number 155. doi: 10.3390/f16010155.
  11. Mamonová, M., Ciglian, D., & Reinprecht, L. (2022). SEM analysis of glued joints of thermally modified wood bonded with pur and pvac glues. Materials, 15, article number 6440. doi: 10.3390/ma15186440.
  12. Mastouri, A., Azadfallah, M., Kamboj, G., Rezaei, F., Tarmian, A., Efhamisisi, D., Mahmoudkia, M., & Corcione, C.E. (2023). Kinetic studies on photo-degradation of thermally-treated spruce wood during natural weathering: Surface performance, lignin and cellulose crystallinity. Construction and Building Materials, 392, article number 131923. doi: 10.1016/j.conbuildmat.2023.131923.
  13. Meger, J., Kozioł, C., Pałucka, M., Burczyk, Ja., & Chybicki, I. (2024). Genetic resources of common ash (Fraxinus excelsior L.) in Poland. BMC Plant Biology, 24, article number 186. doi: 10.1186/s12870-024-04886-z.
  14. Niklewski, J., van Niekerk, P.B., & Marais, B.N. (2023). The effect of weathering on the surface moisture conditions of Norway spruce under outdoor exposure. Wood Material Science & Engineering, 18(4), 1394-1404. doi: 10.1080/17480272.2022.2144444.
  15. Pinchevska, O., Sedliačik, J., Zavialov, D., Lakyda, Y., Baranova, O., Lobchenko, H., & Oliynyk, R. (2022). Insulating wood wool panels using low-grade pine wood. Acta Facultatis Xylologiae Zvolen, 64(1), 15-24. doi: 10.17423/afx.2022.64.1.02.
  16. Rabko, S., Kozel, A., Kimeichuk, I., & Yukhnovskyi, V. (2021). Comparative assessment of some physical and mechanical properties of wood of different scots pine climatypes. Scientific Horizons, 24(2), 27-36. doi: 10.48077/scihor.24(2).2021.27-36.
  17. Stocks, J.J., Metheringham, C.L., & Plumb, W.J. (2019). Genomic basis of European ash tree resistance to ash dieback fungus. Nature Ecology & Evolution, 3, 1686-1696. doi: 10.1038/s41559-019-1036-6.
  18. Tkach, V., Rumiantsev, M., Luk’yanets, V., Kobets, O., Poznіakova, S., Obolonyk, I., & Sydorenko, S. (2020). Common ash (Fraxinus excelsior L.) in Ukrainian forests and its successful natural regeneration. Forestry Studies, 73, 26-42. doi: 10.2478/fsmu-2020-0012.
  19. Ugovšek, A., Šubic, B., Starman, J., Rep, G., Humar, M., Lesar, B., & Lozano, J.I. (2018). Short-term performance of wooden windows and facade elements made of thermally modified and non-modified Norway spruce in different natural environments. Wood Material Science & Engineering, 14(1), 42-47. doi: 10.1080/17480272.2018.1494627.
  20. Vidholdová, Z., Reinprecht, L., & Pánek, M. (2023). The effect of outdoor weathering of thermally modified spruce and pine woods on their surface properties. Acta Facultatis Xylologiae Zvolen, 65, 23-34. doi: 10.17423/afx.2023.65.1.02.
  21. Zelinka, S.L., Altgen, M., Emmerich, L., Guigo, N., Keplinger, T., Kymäläinen, M., & Thybring, E.E. (2022). Review of wood modification and wood functionalization technologies. Forests, 13(7), article number 1004. doi: 10.3390/f13071004.
  22. Zlahtič, M., & Humar, M. (2016). Influence of artificial and natural weathering on the hydrophobicity and surface properties of wood. BioResources, 11(2), 4964-4989. doi: 10.15376/biores.11.2.4964-4989.