Abstract
The chemical treatment of wood has been shown to increase its mechanical strength by forming composites with a variety of polymers. Polyethylene glycol diacrylate (PEGDA) has commonly been used as a polymer reinforcement to increase the strength and resistance of spruce wood for various applications, such as protection from weathering. In this study, PEGDA was impregnated into wood samples and polymerized by dielectric barrier discharge (DBD) plasma to form wood–polymer composites (WPCs). The kinetic rate order of PEGDA was explored using FT-IR quantitative analysis and the DBD plasma-initiated polymerization was determined to be second order. The strength of the wood samples was then determined by a three-point flexural test. The PEGDA-treated spruce wood samples showed improved flexural strength versus the untreated wood samples. The WPCs were also made using a UV treatment method and were then compared to the DBD plasma-treated samples. The results showed that the DBD plasma-treated samples yielded superior flexural strength relative to the UV-treated samples. We accredited this difference in strength to the plasma process and its ability to penetrate into the various layers of the wood and initiate polymerization, as opposed to UV light that can only penetrate superficially, initiating polymerization in only the first few layers of the wood surface.
Highlights
The results showed that the dielectric barrier discharge (DBD) plasma-treated samples yielded superior flexural strength relative to the UV-treated samples
We were able to conclude that the DBD plasma treatment method is a fast and efficient process to polymerize even prepolymers such as Polyethylene glycol diacrylate (PEGDA), achieving a high degree of polymerization after only 10 min of plasma treatment
This was evident by analyzing the Fourier-transform infrared spectroscopy (FT-IR) spectra, which showed the disappearance of several bands associated with the C=C of the acrylate end groups in PEGDA
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Wood and wood-based materials are used in many applications because of their abundance and versatility. Spruce is a widely used wood material for structural elements in construction. There are several disadvantages to using spruce wood in these structural elements, including dimensional/appearance deformation in response to atmospheric conditions, susceptibility to biological attack, and overall degradation with time [1]. Wood treatment seeks to modify the material to overcome these disadvantages
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