Provided is an article, particularly culinary, comprising a cast iron support having two opposite sides. The article comprises a vitreous coating in the form of at least a continuous layer of a sol-gel material comprising a matrix formed from at least a metal polyalkoxylate and at least a reactive or unreactive silicone oil, the layer of sol-gel material being deposited directly on one at least of the sides of said support, and the side provided with a vitreous coating has a surface roughness Ra ranging between 3 and 15 m with a peak count per centimeter RPc ranging between 50 and 200. A method for manufacturing such an article is also provided.

An embodiment of the invention provides a method for forming a magnesium (Mg)-containing coating layer on the surface of a metal support, which comprises a first step of preparing a precursor solution containing a magnesium component, a second step of forming a precipitate on the surface of a metal support by immersing and aging the metal support in the precursor solution prepared in the first step, and a third step of forming a magnesium-containing coating layer on the surface of the metal support by calcinating the precipitate formed in the second step.

A method includes: coating a composition for forming a PZT ferroelectric film not containing Nb on a lower electrode 11 formed on a substrate 10, prebaking the composition, and baking the composition to be crystallized and to thereby form a crystallization promoting layer 12 having a thickness 45 to 90 nm thereon; coating a composition for forming a PNbZT-based ferroelectric film, containing 4 to 10 at % of Nb in 100 at % of all the perovskite B site atoms (Zr, Ti) contained in the composition, on the formed crystallization promoting layer 12 to form a coating film 13a of PNbZT thereon; and pre-baking the coating film 13a and then baking the coating film 13a to be crystallized and to thereby form a PNbZT ferroelectric thin film on the lower electrode 11.

A method for producing a corrosion resistant metal substrate and corrosion resistant metal substrate provided thereby. The method involves forming a plated substrate including a metal substrate provided with a nickel layer or with a nickel and cobalt layer followed by electrodepositing a molybdenum oxide layer from an aqueous solution onto the plated substrate, which is subsequently subjected to an annealing step in a reducing atmosphere to reduce the molybdenum oxide in the molybdenum oxide layer to molybdenum metal in a reduction annealing step and to form a diffusion layer which contains nickel and molybdenum, and optionally cobalt.

A method for coating metallic surfaces with an aqueous composition, which contains an aqueous solution of a zinc salt, by flooding, spraying and/or immersion, wherein, for spraying or immersion, the initial temperature of the substrate lies in the range from 5 to 400? C., in that, for flooding, the initial temperature of the substrate lies in the range from 100 to 400? C. and in that an anticorrosive nanocrystalline zinc oxide layer is formed on the metallic surface. Corresponding aqueous composition, the nanocrystalline zinc oxide layer and the use of the coated substrates are also disclosed.

To provide a PBNZT ferroelectric film capable of preventing sufficiently oxygen ion deficiency. The PBNZT ferroelectric film according to an embodiment of the present invention is a ferroelectric film including a perovskite-structured ferroelectric substance represented by ABO.sub.3, wherein the perovskite-structured ferroelectric substance is a PZT-based ferroelectric substance containing Pb.sup.2+ as A-site ions and containing Zr.sup.4+ and Ti.sup.4+ as B-site ions, and the A-site contains Bi.sup.3+ as A-site compensation ions and the B-site contains Nb.sup.5+ as B-site compensation ions.

A method for producing a corrosion resistant metal substrate and corrosion resistant metal substrate provided thereby. The method involves forming a plated substrate including a metal substrate provided with a nickel layer or with a nickel and cobalt layer followed by electrodepositing a molybdenum oxide layer from an aqueous solution onto the plated substrate, which is subsequently subjected to an annealing step in a reducing atmosphere to reduce the molybdenum oxide in the molybdenum oxide layer to molybdenum metal in a reduction annealing step and to form a diffusion layer which contains nickel and molybdenum, and optionally cobalt.

A thin-film dielectric having a higher dielectric constant than usual ones and not requiring a special single crystal substrate, and a large-capacity thin-film capacitor element using the thin-film dielectric, in which a BaTiO.sub.3-based perovskite solid solution and a KNbO.sub.3-based perovskite solid solution are alternately formed to form a crystal structure gradient region where a lattice constant continuously changes at the interface, and thus crystal lattice strain occurs, thereby permitting the production of a thin-film dielectric having a high dielectric constant; also, a large-capacity thin-film capacitor element can be produced by using the thin-film dielectric of the present invention.

A heterojunction anode for electrolysis is disclosed. The anode has a first conductive metal oxide (FCMO) layer, a second semiconductor layer contacting the FCMO layer, and one or more islands of a third semiconductor contacting the second semiconductor layer. The FCMO layer may be formed on a metallic base, such as titanium. The FCMO layer may include iridium, the second semiconductor layer may include titanium oxide, and the third semiconductor may include tin oxide. The anode may be manufactured using spray pyrolysis to apply each semiconductor material. The anode may be configured such that when placed in an electrolyte at least a portion of the second semiconductor layer and the islands are in direct physical contact with the electrolyte. The second semiconductor interlayer and third semiconductor islands enhance the production of reactive chlorine in chlorinated water. A water treatment system and method using the anode are also disclosed.

Methods are provided for selectively depositing a material on a first surface of a substrate relative to a second, different surface of the substrate. The selectively deposited material can be, for example, a metal, metal oxide, or dielectric material.