![]() Xiao X et al (2016) Investigation into the synergistic effect of nano-sized materials on the anti-corrosion properties of a waterborne epoxy coating. Ramezanzadeh B, Ghasemi E, Mahdavian M, Changizi E, Moghadam MM (2015) Covalently-grafted graphene oxide nanosheets to improve barrier and corrosion protection properties of polyurethane coatings. ![]() Skale S, Doleček V, Slemnik M (2007) Substitution of the constant phase element by Warburg impedance for protective coatings. Tang G, Ren T, Yan Z, Ma L, Hou X, Huang X (2020) "Preparation and anticorrosion resistance of a self‐curing epoxy nanocomposite coating based on mesoporous silica nanoparticles loaded with perfluorooctyl triethoxysilane," J Appl Polym Sci p. ![]() Weng CJ, Chang, CH, Yeh JM (2012) "Polymer nanocomposites in corrosion control," in Corrosion Protection and Control Using Nanomaterials: Elsevier, pp. Hernández-Padrón G, Rojas F, Castaño V (2006) Development and testing of anticorrosive SiO2/phenolic–formaldehydic resin coatings. Njoku DI, Cui M, Xiao H, Shang B, Li Y (2017) Understanding the anticorrosive protective mechanisms of modified epoxy coatings with improved barrier, active and self-healing functionalities: EIS and spectroscopic techniques. Liu J et al (2018) Silane modification of titanium dioxide-decorated graphene oxide nanocomposite for enhancing anticorrosion performance of epoxy coatings on AA-2024. Wang Y et al (2016) Sustainable self-healing at ultra-low temperatures in structural composites incorporating hollow vessels and heating elements. Koch G (2017) "Cost of corrosion," in Trends in oil and gas corrosion research and technologies: Elsevier, pp. Hou B et al (2017) "The cost of corrosion in China," npj Materials Degradation, vol. Jacobson GA (2016) "NACE International’s IMPACT Study Breaks New Ground in Corrosion Management Research and Practice," The Bridge, vol. Sastri VS (2012) Green corrosion inhibitors: theory and practice. Sastri VS (1998) Corrosion inhibitors: principles and applications (no. Quraishi MA, Chauhan DS, Saji VS (2020) Heterocyclic Organic Corrosion Inhibitors: Principles and Applications. Revie RW (2011) Uhlig's corrosion handbook. In this review, the effects of adding the aforementioned nitride nanomaterials to polymer coatings are discussed in terms of the resultant corrosion protection performance, and a comprehensive study on the corrosion resistance of these coatings is conducted.įontana MG (2005) Corrosion engineering. On the other hand, the BN nanoparticles prevent the galvanic corrosion of metal substrates due to their insulating properties. These additives have a high-energy barrier against the penetration of corrosive ions, which leads to excellent corrosion protection properties. Today, inorganic nanomaterials such as nitride nanoparticles such as h-BN, h-BCN, and g-C 3N 4 have significant potential to increase the barrier performance of polymer coatings. Ionic and electron conductivity result in the deterioration of the corrosion properties. Clay contains ions that increase the ionic content and, consequently, the ionic conductivity of the polymer composites. Graphene has a cathodic behavior towards all metals and leads to galvanic corrosion over time. To date, the essential nanomaterials used as reinforcements in polymer matrices are graphene and clay. As a filler, Two-dimensional materials can dramatically change the reduction with economic loss due to their outstanding chemical, mechanical, and thermal properties. For this purpose, one of the most efficient ways is to use new classes of nanocomposite coatings, obtained by the addition of inorganic nanofillers to the polymer matrix, which superior performance over conventional composite coatings. Due to the harmful effects of corrosion in various industries, researchers aim to create more effective coatings with recent nanotechnology advances to prevent the corrosion of materials.
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