Investigation of Impregnation Approach of Zinc Oxide Nano-Dispersions for Potential UV Stabilization in Abies alba and Fagus sylvatica

Compounds Pub Date : 2023-11-01 DOI:10.3390/compounds3040040
Lukas Sommerauer, Alexander Petutschnigg, Thomas Schnabel
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Abstract

As biological material, wood is distinctly affected by to various environmental influences during use. Reductions in durability can come from ultraviolet (UV) radiation, insects, fungi, and microorganisms in both exterior and interior applications. Wood can be easily protected from living organisms via the control of moisture content; however, UV radiation is not so easily managed. Wood components subject to this degradation are damaged and decomposed at a molecular level leading to deterioration of surface quality, especially in visible application areas. A potential remedy to this is using the UV-stabilizing properties of zinc oxide nanoparticles. Zinc oxide nano-dispersions based on propylene glycol (PG) were introduced into the microscopic structure of fir (Abies alba) and beech (Fagus sylvatica) wood by whole-cell impregnation to overcome problems associated with surface coatings. In this work the material uptake of ZnO nano-dispersions in concentrations of 1%, 2%, and 3% w/v were investigated and their effect on the stability of the optical appearance to UV exposure in short-term weathering were evaluated. Untreated reference samples showed significant photo-yellowing. A 1% w/v ZnO dispersion significantly increased the UV stability of treated surfaces. It was found that the uptake of the nano-dispersions was independent of the proportion of ZnO, and that the impregnating agents penetrated fir wood (about 200%) stronger than beech wood (about 70%). Already, a 2% w/v ZnO nano-dispersion led to a saturation of ZnO in the cell structure of the treated wood, for fir as well as beech, and no further ZnO uptake was achieved with 3% w/v nano-dispersions. Scanning electron microscopy shows an agglomeration of ZnO-NP in the cellular pathways impacting penetration, reducing leachability at higher concentrations.
氧化锌纳米分散体浸渍对冷杉和山毛榉潜在紫外线稳定作用的研究
木材作为生物材料,在使用过程中受到各种环境因素的明显影响。耐久性的降低可能来自外部和内部应用中的紫外线(UV)辐射、昆虫、真菌和微生物。通过控制水分含量,木材可以很容易地免受生物体的侵害;然而,紫外线辐射不是那么容易控制的。受到这种降解的木材部件在分子水平上受到破坏和分解,导致表面质量恶化,特别是在可见的应用领域。一种潜在的补救方法是利用氧化锌纳米颗粒的紫外线稳定特性。采用全细胞浸渍的方法,将基于丙二醇(PG)的氧化锌纳米分散体引入冷杉(Abies alba)和山毛榉(Fagus sylvatica)木材的微观结构中,以克服表面涂层相关的问题。本文研究了ZnO纳米分散体在1%、2%和3% w/v浓度下对材料的吸收,并评估了它们对紫外线短期风化下光学外观稳定性的影响。未经处理的对照样品显示明显的光黄。1% w/v的ZnO分散度显著提高了处理表面的紫外线稳定性。研究发现,纳米分散体的吸收与ZnO的比例无关,浸渍剂对杉木(约200%)的渗透能力强于山毛榉木(约70%)。2% w/v的ZnO纳米分散体已经导致处理木材(杉木和山毛榉)的细胞结构中的ZnO饱和,并且在3% w/v的纳米分散体中没有实现进一步的ZnO吸收。扫描电镜显示ZnO-NP在细胞通路中聚集,影响渗透,在较高浓度下降低浸出率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
2.30
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