Wood is a renewable and versatile material comprising cellulose, hemicellulose and lignin as its main structural components, and is widely used for both outdoor and indoor purposes. However, as a lignocellulosic material, wood suffers degradation mainly from UV radiation and moisture uptake. The degraded wood not only loses its strength and dimensional stability, but also its aesthetic appeal. Therefore, it is necessary to protect wood from the above-mentioned agents of degradation. This study focuses on the preparation of a superhydrophobic and UV-resistant coating for the protection of wood. Superhydrophobic coatings are a smart class of coatings which repel water from the surface of wood, thus increasing its longevity. Achieving hydrophobicity is a two-step procedure which includes inducing surface roughness, followed by treatment with a low-surface-energy material. Certain metal oxide nanoparticles like ZnO, CeO₂, and TiO₂ nanoparticles additionally provide protection against UV light along with adequate surface roughness, and materials like silanes act as low-surface-energy materials. A simple one-step method was used to prepare the nanodispersions. ZnO/TiO₂ nanoparticles and silane were mixed together with a suitable non-volatile and non-corrosive solvent, and homogenised together, followed by ultrasonication to obtain the desired nanodispersion. The size of the nanoparticles was analysed using DLS and found to be within 100nm. The solution was then coated on the wood surface. Hydrophobicity was measured using a contact angle analyser and the results were between 150º and 160º, which confirmed the coating's superhydrophobicity. The morphology was analysed using SEM. The coated samples were then tested for UV stability in an indoor accelerated UV weathering tester and were analysed on the basis of their colour change, seen with the help of a HunterLab Labscan XE spectrocolorimeter. The photodegradation of the coated samples was analysed using FTIR. The samples thus exhibited superhydrophobicity as well as UV stability.