A surface protection composition having a compound represented by the formula (1) in an amount of 0.1 to 10 mass % in terms of phosphorus element with respect to the total amount of the composition, the compound (b) the metal-containing compound in an amount of 0.1 to 10 mass % in terms of a metal element with the total amount of the composition or the amine compound in an amount of 0.1 to 5.0 mass % in terms of nitrogen element the total amount of the composition, the compound (c) (meth)acrylate having 2 or more carbon-carbon double bonds and hydrocarbon chains having four or more carbon atoms in an amount of 1.0 to 70 mass % with the total amount of the composition, the compound (d) a photopolymerization initiator in an amount of 0.1 to 10 mass % with the total amount of the composition. ##STR00001##

An electrochemical method for field monitoring of protective properties of organic coatings in seawater environment includes: Step 1: Determine the actual service environment of the coating structure and prepare the simulated electrolyte solution. Step 2: Select the anode block for testing. Step 3: Test the corrosion current and potential of the coating structure under different manual peeling areas. Step 4: Fit the peeling area model of organic coating. Step 5: Real-time monitoring of the actual service coating peeling area. Through the method, we reached to map the deteriorating state of the organic coating to metal substrate for coating on the activity of area of the effect of stripping state recognition, resolved to organic anticorrosive coating anticorrosion performance timely and accurate assessment of the actual problem, achieved by monitoring the anode current to evaluate the organic coating stripping area. This method is scientific and has good technics and broad application value.

The present disclosure relates to a chromium-free coating composition including at least one binder and at least one iron(III)-tris(N,N-dithiocarbamate) complex, where the binder includes at least one synthetic resin and at least one crosslinker. The present disclosure also relates to the use of such a coating composition for the protection against corrosion of metallic substrates, a process for at least partially coating a metallic substrate with such a priming coat, a substrate at least partially coated therewith and an article or a component made of such a substrate.

A wire or cable comprising an insulation layer and a semiconducting shield layer over and in contact with the insulation layer and strippable from the insulation layer, the second semiconducting shield layer made from the composition comprising: (A) 45-52% ethylene vinyl acetate (EVA) comprising 28-45% units derived from vinyl acetate (VA) based on the weight of the EVA; (B) 30-45% carbon black having (1) 80-1 15 milliliters per 100 grams (ml/100 g) DBP absorption value, (2) 30-60 milligrams per gram (mg/g) iodine absorption (I2NO), and (3) 0.3-0.6 grams/milliliter (g/ml) apparent density; (C) 5-20% acrylonitrile butadiene rubber (NBR) comprising 25-55% units derived from acrylonitrile (AN) based on the weight of the NBR; (D) 0.2-2% phenolic antioxidant; and (E) 0.5-2% organic peroxide.

Methods and materials for providing corrosion protection for atomically thin materials are described. In some embodiments, an atomically thin material may have a coating that includes one or more alkyl amine species. The coating may cover at least a portion of the atomically thin material, and the coating may form a corrosion protection layer. Depending on the particular materials, a coating may be ionically bonded to at least a portion of an atomically thin material. In some embodiments, a method of forming a corrosion protection layer on at least a portion of an atomically thin material may involve exposing at least a portion of an atomically thin material that corrodes under normal atmospheric conditions to an alkyl amine.

A thin oil film having parylene irregular dendritic-like columns extending from one side to another exhibits hydrophobic properties that can be used as a corrosion resistant coating or water-repellant, biofouling resistant surface. This parylene-in-oil layer can be paired with an adjacent layer of solid parylene that it overlays or underlays. The solid parylene cross polymerizes with the parylene dendrites, keeping them in place as well as the oil film. The parylene dendrites are fabricated by chemical vapor deposition (CVD) of parylene over the oil layer, the dendrites self-forming from the bottom to the top. Continued CVD over the dendrites can produce a top layer of solid parylene. Etching the solid parylene away can result in a water repellant, anti-biofouling surface.

A corrosion inhibition composition is disclosed comprising a zinc oxide, a zinc phosphate, a calcium silicate, an aluminum phosphate, a zinc calcium strontium aluminum orthophosphate silicate hydrate, a molybdate compound, a silicate compound, and a zinc phthalate compound.

The present disclosure generally relates to insulation articles including corrosion inhibitors and methods of producing the same are disclosed. In some embodiments, an article of manufacture comprising an insulation mat comprising an uncured combination of a plurality of randomly oriented fibers and a binder is provided. In further embodiments, the insulation mat extends between a first surface and a second surface, and a veil attached to the first surface and structured to inhibit physical movement of the cured combination through the veil is provided, as well as a metal sheet attached to the second surface by a water-containing adhesive contacting the metal sheet and the second surface, and a corrosion inhibitor composition deposited on the cured combination of the insulation mat, wherein the corrosion inhibitor composition is capable of modifying toward neutral a pH of the cured combination in contact with water from the water-containing adhesive.

Use of dithiophosphinic acids of the general formula HS.sub.2P(R.sup.1)(R.sup.2) and/or salts thereof for producing chrome-free, polymer-containing corrosion control layers on metallic surfaces, R.sup.1 and R.sup.2 independently of one another each being organic radicals having 1 to 30 C atoms.

A composition for forming an electroactive coating is described, including an acid as a polymerization catalyst, at least one functional component, and at least one compound of formula (1) as a monomer: ##STR00001##
wherein X is selected from S, O, Se, Te, PR.sup.2 and NR.sup.2, Y is hydrogen (H) or a precursor of a good leaving group Y.sup. whose conjugate acid (HY) has a pK.sub.a of less than 30, Z is hydrogen (H), silyl, or a good leaving group whose conjugate acid (HY) has a pK.sub.a of less than 30, b is 0, 1 or 2, each R.sup.1 is a substituent, and the at least one compound of formula (1) includes at least one compound of formula (1) with Z=H and YH.