The present disclosure provides a transparent alumina-based plate, and a hot-pressing method to make the transparent alumina-based plate from platelet alumina. Alumina powder with a platelet morphology was hot-pressed to transparency with pre-load pressures of about 0-8 MPa, maximum temperatures of about 1750-1825° C., maximum pressures of about 2.5-80 MPa, and isothermal hold times of 1-7 hours. A novel alumina-based plate has been prepared, wherein the plate has a thickness of 2-5 mm, an in-line transmission of at least 60-75% for a light with a wavelength range of 645-2500 nm, an in-line transmission variance of <15% over the wavelength range of 645-2500 nm, and a relative density of 99.00-99.95%.

A blended composition containing uncoated Al.sub.2O.sub.3 flakes having a thickness of ≥500 nm and a D.sub.50-value of 15-30 μm and a D.sub.90-value of 30-45 μm, and/or coated Al.sub.2O.sub.3 flakes having a thickness of ≥500 nm and a D.sub.50-value of 15-30 μm and a D.sub.90-value of 30-45 μm, which have been coated with at least one layer of a metal oxide, mixtures of at least two metal oxides, metal, metal sulphide, titanium suboxide, titanium oxynitride, FeO(OH), metal alloys and/or rare earth compounds, and their use in various formulations.

A blended composition containing uncoated Al.sub.2O.sub.3 flakes having a thickness of ≥500 nm and a D.sub.50-value of 15-30 μm and a D.sub.90-value of 30-45 μm, and/or coated Al.sub.2O.sub.3 flakes having a thickness of ≥500 nm and a D.sub.50-value of 15-30 μm and a D.sub.90-value of 30-45 μm, which have been coated with at least one layer of a metal oxide, mixtures of at least two metal oxides, metal, metal sulphide, titanium suboxide, titanium oxynitride, FeO(OH), metal alloys and/or rare earth compounds, and their use in various formulations.

A dielectric composition including a metal oxide particle including a diameter of 5 nanometers or less capped with an organic ligand at at least a 1:1 ratio. A method including synthesizing metal oxide particles including a diameter of 5 nanometers or less; and capping the metal oxide particles with an organic ligand at at least a 1:1 ratio. A method including forming an interconnect layer on a semiconductor substrate; forming a first hardmask material and a different second hardmask material on the interconnect layer, wherein at least one of the first hardmask material and the second hardmask material is formed over an area of interconnect layer target for a via landing and at least one of the first hardmask material and the second hardmask material include metal oxide nanoparticles; and forming an opening to the interconnect layer selectively through one of the first hardmask material and the second hardmask material.

A dielectric composition including a metal oxide particle including a diameter of 5 nanometers or less capped with an organic ligand at at least a 1:1 ratio. A method including synthesizing metal oxide particles including a diameter of 5 nanometers or less; and capping the metal oxide particles with an organic ligand at at least a 1:1 ratio. A method including forming an interconnect layer on a semiconductor substrate; forming a first hardmask material and a different second hardmask material on the interconnect layer, wherein at least one of the first hardmask material and the second hardmask material is formed over an area of interconnect layer target for a via landing and at least one of the first hardmask material and the second hardmask material include metal oxide nanoparticles; and forming an opening to the interconnect layer selectively through one of the first hardmask material and the second hardmask material.

An abrasive particle having a body and a coating overlying the body, the coating including an amorphous material and at least one filler contained within the amorphous material. The abrasive particle may be included in a fixed abrasive article.

An abrasive particle having a body and a coating overlying the body, the coating including an amorphous material and at least one filler contained within the amorphous material. The abrasive particle may be included in a fixed abrasive article.

Provided is an absorption method of an element belonging to periods 4 to 6 and groups 3 to 15 of the periodic table. The method includes: preparing mesoporous alumina that satisfies at least one of the following items: (1) a surface hydroxyl content is 3.5 mmol/g or more; (2) a low-temperature CO.sub.2 desorption amount in CO.sub.2 thermal desorption amount spectrometry is 5 .Math.mol/g or more; and (3) a low-temperature NH.sub.3 desorption amount in NH.sub.3 thermal desorption amount spectrometry is 25 .Math.mol/g or more; and bringing a liquid containing an absorption target element in contact with the mesoporous alumina to absorb the absorption target element in the mesoporous alumina. The absorption target element is at least one type selected from the group consisting of an element belonging to periods 4 to 6 and groups 3 to 15 of the periodic table.

Provided is an absorption method of an element belonging to periods 4 to 6 and groups 3 to 15 of the periodic table. The method includes: preparing mesoporous alumina that satisfies at least one of the following items: (1) a surface hydroxyl content is 3.5 mmol/g or more; (2) a low-temperature CO.sub.2 desorption amount in CO.sub.2 thermal desorption amount spectrometry is 5 .Math.mol/g or more; and (3) a low-temperature NH.sub.3 desorption amount in NH.sub.3 thermal desorption amount spectrometry is 25 .Math.mol/g or more; and bringing a liquid containing an absorption target element in contact with the mesoporous alumina to absorb the absorption target element in the mesoporous alumina. The absorption target element is at least one type selected from the group consisting of an element belonging to periods 4 to 6 and groups 3 to 15 of the periodic table.

A spherical alumina powder having a maximum particle diameter showing a maximum peak in the range of 35 to 70 μm, a frequency of 5 to 15%, and an accumulated value of frequencies respectively at 20 particle diameter points, obtained by dividing a particle diameter range of 1 to 20 μm equally into 19 sections, of 3 to 17% by volume, the powder providing a ratio (V.sub.Y/V.sub.X) of a viscosity V.sub.Y of a resin composition Y to a viscosity V.sub.X of a resin composition X of 0.85 or more, composition X containing the powder and a vinyl group-containing polymethylsiloxane, the powder being contained in an amount of 88.1% by mass, the resin composition Y being the same as X except for containing the same powder as in composition X in an amount of 79.3% by mass and containing a powder for testing in an amount of 8.8% by mass.