A method for producing plated-through holes in printed circuit boards and to printed circuit boards produced in this manner.

A method for forming an oxidation protection system on a carbon-carbon composite structure can comprise applying a boron slurry to the carbon-carbon composite structure, wherein the boron slurry comprises a boron compound, a first glass mixture, a first glass former, a first glass modifier, and a first carrier fluid, the first glass mixture including a first glass compound and a second glass compound, the first glass compound having a first viscosity-temperature profile that is at least one order of magnitude below a second viscosity-temperature profile of the second glass compound; applying a silicon slurry to the carbon-carbon composite structure, wherein the silicon slurry comprises a silicon compound, a third glass compound, a second glass former, a second glass modifier, and a second carrier fluid; and heating the carbon-carbon composite structure.

A method for forming an oxidation protection system on a carbon-carbon composite structure can comprise applying a boron slurry to the carbon-carbon composite structure, wherein the boron slurry comprises a boron compound, a first glass mixture, a first glass former, a first glass modifier, and a first carrier fluid, the first glass mixture including a first glass compound and a second glass compound, the first glass compound having a first viscosity-temperature profile that is at least one order of magnitude below a second viscosity-temperature profile of the second glass compound; applying a silicon slurry to the carbon-carbon composite structure, wherein the silicon slurry comprises a silicon compound, a third glass compound, a second glass former, a second glass modifier, and a second carrier fluid; and heating the carbon-carbon composite structure.

A coating system for coating inorganic substrates with a wide range of functional materials without having to use the usually necessary high temperatures includes an aqueous solution as component K1, which aqueous solution contains at least Al(H.sub.2PO.sub.4).sub.3 and Al(NaHPO.sub.4).sub.3 in the following fractions on an oxide basis and in mass percent with respect to the total mass of the solution: P.sub.2O.sub.5=25.0 to 37.0, Al.sub.2O.sub.3=5.8 to 9.0, Na.sub.2O=0.1 to 2.0, and H.sub.2O=54.0 to 66.0, and which includes an additional component K2 having the constituents magnesium oxide, silicate, and borate, which are contained in K2 in the following fractions on an oxide basis and in mass percent with respect to the total mass of component K2: MgO=70.0 to 95.0, SiO.sub.2=1.0 to 19.0, and B.sub.2O.sub.3=1.0 to 3.0, wherein there is a reactivity of the magnesium oxide of 40 to 400 seconds in the citric acid test and the loss on ignition of component K2 is 0 to 3.0.

A coating system for coating inorganic substrates with a wide range of functional materials without having to use the usually necessary high temperatures includes an aqueous solution as component K1, which aqueous solution contains at least Al(H.sub.2PO.sub.4).sub.3 and Al(NaHPO.sub.4).sub.3 in the following fractions on an oxide basis and in mass percent with respect to the total mass of the solution: P.sub.2O.sub.5=25.0 to 37.0, Al.sub.2O.sub.3=5.8 to 9.0, Na.sub.2O=0.1 to 2.0, and H.sub.2O=54.0 to 66.0, and which includes an additional component K2 having the constituents magnesium oxide, silicate, and borate, which are contained in K2 in the following fractions on an oxide basis and in mass percent with respect to the total mass of component K2: MgO=70.0 to 95.0, SiO.sub.2=1.0 to 19.0, and B.sub.2O.sub.3=1.0 to 3.0, wherein there is a reactivity of the magnesium oxide of 40 to 400 seconds in the citric acid test and the loss on ignition of component K2 is 0 to 3.0.

The disclosure provides for an article including a substrate, an environmental barrier coating (EBC), a bondcoat and a boron source. The substrate may include a silicon-including ceramic material. The EBC may be disposed over the substrate, and the bondcoat may disposed between the substrate and the EBC. The bondcoat may include silicon. The boron source may be disposed within the article to provide an effective amount of boron to form an oxide including silicon and at least 0.1 weight percent boron during exposure of the bondcoat to an oxidizing environment at a temperature greater than 900 degrees Celsius. The oxide may be a borosilicate glass that is substantially devitrification resistant to prevent spallation of the EBC and thereby enhance the temperature capability of the article.

The disclosure provides for an article including a substrate, an environmental barrier coating (EBC), a bondcoat and a boron source. The substrate may include a silicon-including ceramic material. The EBC may be disposed over the substrate, and the bondcoat may disposed between the substrate and the EBC. The bondcoat may include silicon. The boron source may be disposed within the article to provide an effective amount of boron to form an oxide including silicon and at least 0.1 weight percent boron during exposure of the bondcoat to an oxidizing environment at a temperature greater than 900 degrees Celsius. The oxide may be a borosilicate glass that is substantially devitrification resistant to prevent spallation of the EBC and thereby enhance the temperature capability of the article.

A ceramic component is provided that includes a silicon-based layer comprising a silicon-containing material (e.g., a silicon metal and/or a silicide) and a boron-doped refractory compound, such as about 0.001% to about 85% by volume of the boron-doped refractory compound (e.g., about 1% to about 60% by volume of the boron-doped refractory compound). A coated component is also provided that includes a CMC component defining a surface; a bond coating directly on the surface of the CMC component, with the bond coating comprises a silicon-containing material and a boron-doped refractory compound (e.g., about 0.1% to about 25% of the boron-doped refractory compound); a thermally grown oxide layer on the bond coating; and an environmental barrier coating on the thermally grown oxide layer.

A ceramic component is provided that includes a silicon-based layer comprising a silicon-containing material (e.g., a silicon metal and/or a silicide) and a boron-doped refractory compound, such as about 0.001% to about 85% by volume of the boron-doped refractory compound (e.g., about 1% to about 60% by volume of the boron-doped refractory compound). A coated component is also provided that includes a CMC component defining a surface; a bond coating directly on the surface of the CMC component, with the bond coating comprises a silicon-containing material and a boron-doped refractory compound (e.g., about 0.1% to about 25% of the boron-doped refractory compound); a thermally grown oxide layer on the bond coating; and an environmental barrier coating on the thermally grown oxide layer.

A composition is generally provided that includes a silicon-containing material (e.g., silicon metal and/or a silicide) and a boron-doped refractory compound, such as about 0.001% to about 85% by volume of the boron-doped refractory compound (e.g., about 1% to about 60% by volume). In one embodiment, a bond coating on a surface of a ceramic component is generally provided with the bond coating including such a composition, with the silicon-containing material is silicon metal.