| Abstract | Wood is a widely used construction material that has many advantageous properties. However, it sufers from weaknesses such as low-dimensional stability and low durability in humid environments. These issues are associated with the porous vascular structure of wood that leads to a high water uptake capacity. This research aims to reduce the water uptake capacity of spruce wood by dip-coating samples in an aqueous colloid of silicon dioxide (SiO₂) nanoparticles. SiO₂ is a dense ceramic material with good chemical stability. It is readily available and afordable, making it an excellent candidate for this application. This study investigates the efect of SiO₂ impregnation on the physico-mechanical properties of spruce wood. Density measurements, water uptake tests, microscopy examination, thermogravimetric analysis, and dynamic mechanical analysis were conducted on non-treated and SiO₂-treated spruce wood samples. Quantitative and qualitative analyses demonstrated that SiO₂ impregnation performed under higher vacuum pressure was more efective compared to the atmospheric condition and exhibited a greater presence of SiO₂ in the wood’s vascular system. SiO₂ impregnation under vacuum pressure demonstrated an efective increase in the density of the wood. It also reduced the porosity, which led to a signifcant reduction in the water uptake of the spruce wood. The analysis of the wood viscoelastic properties revealed that SiO₂ impregnation under atmospheric and vacuum conditions triggered two diferent reinforcing mechanisms. The results showed that a signifcant improvement of the spruce wood storage and loss moduli could be achieved when impregnation was performed at the highest vacuum pressure of−90 kPa. |
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