SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3134102573> ?p ?o ?g. }

Showing items 1 to 100 of ±226 with 100 items per page.

W3134102573 endingPage "106218" @default.
W3134102573 startingPage "106218" @default.
W3134102573 abstract "• Types of various nanocarriers systems. • Functions of nanocarriers for corrosion protection. • Characteristic techniques for nanocarrier based smart coatings. • Applications of smart nanocarriers. • Future prospective of nanocarriers. Steel-made infrastructures have been expanding at an incredible rate worldwide and are critical for the expansion and operation of countless industries. Steel is susceptible to corrosion failures, particularly in aggressive environments, and requires surface protection and effective corrosion management to avoid failures. Corrosion failures are a serious and costly problem. In the Middle East region, the direct costs of corrosion are estimated at around 5% of the gross domestic profit (GDP). The indirect costs are much higher and often unpredictable. Given the economic importance of steel-made infrastructures, its corrosion creates major problems for many industries, namely the oil and gas industry, and is responsible for very high operational expenditures (OPEX). Consequently, the coating industry is under constant pressure, as they need to supply the best coatings to the end-users, ensuring adequate corrosion protection and compliance with the environmental requirements. Corrosion protective coatings are the prime choice for steel protection and are, nowadays, the focus of considerable attention and intense research effort. The reason is that there is an extraordinary increase in environmental consciousness that has been accompanied by new legislation and regulations that concern people's safety, assets sustainability, reliability, and protection of the environment. This scenario poses an enormous challenge to the industry: how to comply with these requirements while keeping competitive solutions and sustainable operations and maintenance costs. Smart multifunctional coatings are providing a viable solution to address the corrosion challenges in a wide range of industries due to their promising self-healing properties. The targeted properties of smart multifunctional coatings are deeply influenced by the type of functionalities, pigments (including smart carriers), inhibitors, self-healing agents, the matrix itself, and the synthesis route. A large variety of anti-corrosion pigments have been designed and used as smart carriers to encapsulate/load various types of inhibitors and/or self-healing agents. In this review, we summarized the recent developments made in the field of pigments used as smart carriers for corrosion protection of steel in numerous industrial applications. Various nanocarriers, also referred to as smart nanocarriers, have been reported comprising of inorganic, organic, and hybrid scaffolds and used as additives in coatings for corrosion protection of different materials. This review also includes various characterization techniques employed to evaluate the self-healing performance of coatings modified with smart carriers. Besides, commendable advances, there is still the need for progress in designing novel smart carriers compatible with different coatings matrices and able to be loaded with various chemical species to enhance the corrosion protection ability and self-healing performance. It is, therefore, essential to review the earliest developments made so far for a better understanding of the existing strategies. A concise overview on this topic will provide a robust scientific background and will serve as a baseline to synthesize future novel smart carriers for developing anti-corrosion coatings with improved self-healing performance. Overall, such systems are expected to serve as facilitators for better corrosion management of coated steel parts." @default.
W3134102573 created "2021-03-15" @default.
W3134102573 creator A5034942141 @default.
W3134102573 creator A5043413923 @default.
W3134102573 creator A5060141733 @default.
W3134102573 date "2021-05-01" @default.
W3134102573 modified "2023-09-24" @default.
W3134102573 title "A focused review on smart carriers tailored for corrosion protection: Developments, applications, and challenges" @default.
W3134102573 cites W1436171113 @default.
W3134102573 cites W1491994879 @default.
W3134102573 cites W1545779749 @default.
W3134102573 cites W1829124071 @default.
W3134102573 cites W1966136237 @default.
W3134102573 cites W1966893244 @default.
W3134102573 cites W1967760164 @default.
W3134102573 cites W1967901144 @default.
W3134102573 cites W1971797824 @default.
W3134102573 cites W1972097026 @default.
W3134102573 cites W1975139160 @default.
W3134102573 cites W1978818556 @default.
W3134102573 cites W1979495712 @default.
W3134102573 cites W1979619906 @default.
W3134102573 cites W1979804382 @default.
W3134102573 cites W1980471741 @default.
W3134102573 cites W1981782713 @default.
W3134102573 cites W1982767554 @default.
W3134102573 cites W1983563748 @default.
W3134102573 cites W1984015287 @default.
W3134102573 cites W1986269944 @default.
W3134102573 cites W1986849434 @default.
W3134102573 cites W1989283128 @default.
W3134102573 cites W1997084863 @default.
W3134102573 cites W1997391723 @default.
W3134102573 cites W2001183295 @default.
W3134102573 cites W2002383098 @default.
W3134102573 cites W2002424045 @default.
W3134102573 cites W2002897887 @default.
W3134102573 cites W2003323748 @default.
W3134102573 cites W2006110458 @default.
W3134102573 cites W2006198890 @default.
W3134102573 cites W2006900646 @default.
W3134102573 cites W2007521923 @default.
W3134102573 cites W2010463032 @default.
W3134102573 cites W2012819183 @default.
W3134102573 cites W2013981336 @default.
W3134102573 cites W2014054662 @default.
W3134102573 cites W2016664129 @default.
W3134102573 cites W2018471229 @default.
W3134102573 cites W2018476602 @default.
W3134102573 cites W2020542275 @default.
W3134102573 cites W2024146040 @default.
W3134102573 cites W2025104530 @default.
W3134102573 cites W2025922478 @default.
W3134102573 cites W2027132460 @default.
W3134102573 cites W2028488037 @default.
W3134102573 cites W2030979932 @default.
W3134102573 cites W2031622997 @default.
W3134102573 cites W2032674777 @default.
W3134102573 cites W2033776528 @default.
W3134102573 cites W2034094242 @default.
W3134102573 cites W2034324164 @default.
W3134102573 cites W2041723514 @default.
W3134102573 cites W2043025413 @default.
W3134102573 cites W2043708961 @default.
W3134102573 cites W2051967345 @default.
W3134102573 cites W2052916799 @default.
W3134102573 cites W2054925718 @default.
W3134102573 cites W2055063128 @default.
W3134102573 cites W2055182495 @default.
W3134102573 cites W2056777003 @default.
W3134102573 cites W2058005393 @default.
W3134102573 cites W2059115909 @default.
W3134102573 cites W2060321929 @default.
W3134102573 cites W2060783076 @default.
W3134102573 cites W2062701023 @default.
W3134102573 cites W2063991589 @default.
W3134102573 cites W2065866278 @default.
W3134102573 cites W2068416565 @default.
W3134102573 cites W2069474251 @default.
W3134102573 cites W2070188030 @default.
W3134102573 cites W2071408973 @default.
W3134102573 cites W2072135290 @default.
W3134102573 cites W2077767745 @default.
W3134102573 cites W2077891697 @default.
W3134102573 cites W2080691489 @default.
W3134102573 cites W2082810894 @default.
W3134102573 cites W2084072190 @default.
W3134102573 cites W2084133270 @default.
W3134102573 cites W2088267349 @default.
W3134102573 cites W2089730202 @default.
W3134102573 cites W2089961610 @default.
W3134102573 cites W2092961413 @default.
W3134102573 cites W2093491169 @default.
W3134102573 cites W2096470195 @default.
W3134102573 cites W2099252886 @default.
W3134102573 cites W2100775911 @default.
W3134102573 cites W2110111661 @default.
W3134102573 cites W2112581908 @default.