Abstract
Soiling of external surfaces is an increasing issue for conservation of architectural heritage. Providing architectural surfaces with self-cleaning ability is one of the most promising routes of preventive conservation. To this aim, several methods have been proposed in the literature, based on the use of photocatalytic TiO2 nanoparticles, either directly applied onto the surfaces or incorporated in protective coatings. However, when nano-TiO2 is directly applied onto architectural surfaces, the particles are easily removed by rain. When TiO2 is incorporated in polymeric coatings, durability issues arise as well, because the photoactivity of TiO2 nanoparticles can promote degradation of the polymer. Here, we present an innovative alternative method, based on combination of TiO2 nanoparticles and hydroxyapatite (HAP). The incorporation of nano-TiO2 into an HAP coating protects the nanoparticles from leaching by rain, thanks to the chemical bonding between TiO2 and HAP, without diminishing their photoactivity. As a result, marble treated with HAP-TiO2 composites exhibits high self-cleaning ability and high durability, with results superior to those achieve by direct application of nano-TiO2 onto the surface, as frequently performed on site.
Highlights
Soiling of external surfaces by particulate matter present in the atmosphere is extremely important for cultural heritage conservation
Several methods have been proposed in the literature, based on the use of photocatalytic TiO2 nanoparticles, either directly applied onto the surfaces or incorporated in protective coatings
When nano-TiO2 is directly applied onto architectural surfaces, the particles are removed by rain
Summary
Soiling of external surfaces by particulate matter present in the atmosphere is extremely important for cultural heritage conservation. Because of the weak adhesion between the particles and the substrate, nano-TiO2 directly applied onto historic surfaces is removed by rain [2]. This led to the second approach, i.e. incorporating the particles into coatings aimed at protecting them from leaching by rain. Coatings of various types have been proposed, including inorganic, organic and hybrid coatings. This approach has the advantage that particles are protected from leaching and mechanical strengthening can be achieved by a single treatment.
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