A coated member manufacturing method includes: an application step for applying a magnesium hydroxide solution on a surface of a FeCo-based alloy base material; and a baking step for baking the base material after the application step at 600-900? C. to form a magnesium oxide coating on the base material. This coated member has, on a FeCo-based alloy base material, a baked coating of magnesium oxide having a lattice constant of 4.20-4.23 ?.

The present disclosure relates to a material comprising an oxide of an alkaline earth metal, wherein the oxide of the alkaline earth metal is doped with an anion. In particular embodiments, the material comprises MgO doped with an anion selected from the group consisting of chloride, sulfate, phosphate and any mixtures thereof. The present disclosure also relates to a method for preparing the material, a method for adsorbing CO2 from an environment and the use of the material to adsorb CO2 from an environment.

The present disclosure relates to a material comprising an oxide of an alkaline earth metal, wherein the oxide of the alkaline earth metal is doped with an anion. In particular embodiments, the material comprises MgO doped with an anion selected from the group consisting of chloride, sulfate, phosphate and any mixtures thereof. The present disclosure also relates to a method for preparing the material, a method for adsorbing CO2 from an environment and the use of the material to adsorb CO2 from an environment.

The invention provides a method of producing an annealing separator, an annealing separator and a grain-oriented magnetic steel. An annealing separator obtained by the method has high purity and excellent dispersibility and bonding strength, thus allowing formation of a uniform, dense forsterite layer on the surface of a grain-oriented magnetic steel. The method of producing an annealing separator comprises the following steps: step (1) in which magnesium oxide and an ammonium salt solution are mixed and reacted to prepare a magnesium salt solution and ammonia, and then the purified magnesium salt solution and the ammonia are reacted to obtain magnesium hydroxide, step (2) in which one portion of the obtained magnesium hydroxide is subjected to high temperature ageing at 155 to 230? C. while another portion of the obtained magnesium hydroxide is subjected to low temperature ageing at 10 to 100? C., and step (3) in which the magnesium hydroxides aged under the different conditions are mixed and burned to obtain magnesium oxide for use as an annealing separator.

The invention provides a method of producing an annealing separator, an annealing separator and a grain-oriented magnetic steel. An annealing separator obtained by the method has high purity and excellent dispersibility and bonding strength, thus allowing formation of a uniform, dense forsterite layer on the surface of a grain-oriented magnetic steel. The method of producing an annealing separator comprises the following steps: step (1) in which magnesium oxide and an ammonium salt solution are mixed and reacted to prepare a magnesium salt solution and ammonia, and then the purified magnesium salt solution and the ammonia are reacted to obtain magnesium hydroxide, step (2) in which one portion of the obtained magnesium hydroxide is subjected to high temperature ageing at 155 to 230? C. while another portion of the obtained magnesium hydroxide is subjected to low temperature ageing at 10 to 100? C., and step (3) in which the magnesium hydroxides aged under the different conditions are mixed and burned to obtain magnesium oxide for use as an annealing separator.

The invention is referred to chemical technology, namely to active high-purity magnesium oxide and its production method. Active high-purity magnesium oxide, including the surface treated one, has BET specific surface area from 70 to 200 m.sup.2/g, average particle size (d50) determined by laser diffraction method not more than 10 microns, iodine activity in the range from 70 to 200 mg J/g MgO, citric activity not more than 40 s, pore volume in the range from 3.2?10.sup.?2 cm.sup.3/g to 10.2?10.sup.?2 cm.sup.3/g, diameter of 10% of the particles not more than 2 microns, diameter of 90% of the particles not more than 30 microns, mass fraction of residue on the 150 micron sieve not more than 1%, mass fraction of residue on the 45 micron sieve not more than 2%, mass fraction of chlorides not more than 0.1%, mass fraction of calcium not more than 0.1%, mass fraction of substances insoluble in hydrochloric acid not more than 0.05%, mass fraction of iron not more than 0.005%, mass fraction of impurities of each of Ti, Co, Mo, V, Sb, Ba cations not more than 1 ppm, Pb, Cd, As, Hg not more than 0.1 ppm.

The invention is referred to chemical technology, namely to active high-purity magnesium oxide and its production method. Active high-purity magnesium oxide, including the surface treated one, has BET specific surface area from 70 to 200 m.sup.2/g, average particle size (d50) determined by laser diffraction method not more than 10 microns, iodine activity in the range from 70 to 200 mg J/g MgO, citric activity not more than 40 s, pore volume in the range from 3.2?10.sup.?2 cm.sup.3/g to 10.2?10.sup.?2 cm.sup.3/g, diameter of 10% of the particles not more than 2 microns, diameter of 90% of the particles not more than 30 microns, mass fraction of residue on the 150 micron sieve not more than 1%, mass fraction of residue on the 45 micron sieve not more than 2%, mass fraction of chlorides not more than 0.1%, mass fraction of calcium not more than 0.1%, mass fraction of substances insoluble in hydrochloric acid not more than 0.05%, mass fraction of iron not more than 0.005%, mass fraction of impurities of each of Ti, Co, Mo, V, Sb, Ba cations not more than 1 ppm, Pb, Cd, As, Hg not more than 0.1 ppm.

The present invention provides a magnesium oxide powder capable of restraining the deformation of the internal circumferential shape of an annealed coil, and further giving a sufficiently uniform coat external appearance after the annealing; and a method for producing the powder. The magnesium oxide powder of the invention is a magnesium oxide powder including an Fe element, wherein a content of the Fe element is from 0.03 to 0.20% by weight, and at least a part of the Fe element has a cluster structure.

The present invention provides a magnesium oxide powder capable of restraining the deformation of the internal circumferential shape of an annealed coil, and further giving a sufficiently uniform coat external appearance after the annealing; and a method for producing the powder. The magnesium oxide powder of the invention is a magnesium oxide powder including an Fe element, wherein a content of the Fe element is from 0.03 to 0.20% by weight, and at least a part of the Fe element has a cluster structure.

Nanowires useful as heterogeneous catalysts are provided. The nanowire catalysts are useful in a variety of catalytic reactions, for example, the oxidative coupling of methane to C2 hydrocarbons. Related methods for use and manufacture of the same are also disclosed.