Abstract
The ingress of water, as a vehicle for many harmful substances, is the main cause of all the major physical and chemical degradation processes affecting concrete buildings. To prevent damage and protect concrete surfaces, coatings are generally used. Cement-based coatings in particular can act as a physical barrier and reduce the permeability of surfaces. In case of chloride-induced corrosion, corrosion inhibitors are also generally used, and nano-carriers have been proven to provide a long-term protective effect. In this work, we designed a surface protection cementitious coating enhanced with nano-silica and halloysite nanotubes (HNTs). HNTs were loaded with a corrosion inhibitor, benzotriazole (BTA), and used as nano-reservoir, while nano-silica was used to improve the structure of the protective coating and to strengthen its adhesion to the surface of application. The cementitious coatings were characterized with a multi-technique approach including thermal and spectroscopic analysis, scanning electron microscopy, specific surface area and pore size distribution, and Vickers hardness test. The release of BTA was monitored through UV-vis analysis, and the transportation of BTA through coated mortars was studied in simulated rain conditions. We evidenced that the presence of silica densifies the porous structure and increases the interfacial bond strength between the protective coating and the surface of application. We report here, for the first time, that HNTs can be used as nano-carriers for the slow delivery of anti-corrosion molecules in cement mortars.
Highlights
The durability of concrete structures strongly depends on their surface permeability [1,2].When surfaces are exposed to external environmental agents, the complex network of pores and capillaries that exists in dried cementitious materials allows for the ingress of potentially dangerous substances, leading to deterioration and affecting long-term performance durability [2,3]
We gained information on the composition of the Through thermogravimetric analysis, we gained information on the composition of the surface protection cementitious formulations after 28 days of curing, and we evaluated the effect of surface protection cementitious formulations after 28 days of curing, and we evaluated the effect of silica and halloysite nanotubes (HNTs) on the hydration reactions occurring in cement pastes
This study explored the effects of HNTs and nano-silica in cement mortars
Summary
When surfaces are exposed to external environmental agents, the complex network of pores and capillaries that exists in dried cementitious materials allows for the ingress of potentially dangerous substances, leading to deterioration and affecting long-term performance durability [2,3]. The ingress of water, as a vehicle for all the harmful substances, is the main cause of all the major physical and chemical degradation processes affecting concrete structures, the research on protective treatments of cement-based structures is extensive [3,4,5,6]. The authors reported the study of a cement mortar
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