Various aspects of the present disclosure relate to a method of cleaning a glass substrate. The method includes contacting the glass substrate with a cleaning agent for a predetermined amount of time. The cleaning agent includes a substance having a sublimation point in a range of from about ?90? C. to about ?70? C. and the cleaning agent is dispersed in a gas carrier.

Various aspects of the present disclosure relate to a method of cleaning a glass substrate. The method includes contacting the glass substrate with a cleaning agent for a predetermined amount of time. The cleaning agent includes a substance having a sublimation point in a range of from about ?90? C. to about ?70? C. and the cleaning agent is dispersed in a gas carrier.

A method of creating a protective coating on an alkali metal hydroxide-containing solid is provided. The method includes providing carbon dioxide to an alkali metal hydroxide-containing solid and allowing the alkali metal hydroxide and carbon dioxide to react thereby forming a carbonate or bicarbonate-containing layer on the exterior of the solid wherein the carbonate or bicarbonate-containing layer is non-hygroscopic and water soluble, and wherein greater than 80% of the hydroxide in the hydroxide-containing solid does not react with the carbon dioxide, and further wherein the alkali metal hydroxide-containing solid is substantially free of lithium hydroxide. A method of testing for the presence of carbonate-containing coating on an alkali metal hydroxide containing solid is also provided. The method includes exposing the coated solid to 95 weight percent ethanol, collecting the ethanol effluent and testing the effluent for alkali metal hydroxide. A suitably coated solid does not have dissolved alkali metal hydroxide in the ethanol effluent or is substantially free of alkali metal hydroxide.

A method of creating a protective coating on an alkali metal hydroxide-containing solid is provided. The method includes providing carbon dioxide to an alkali metal hydroxide-containing solid and allowing the alkali metal hydroxide and carbon dioxide to react thereby forming a carbonate or bicarbonate-containing layer on the exterior of the solid wherein the carbonate or bicarbonate-containing layer is non-hygroscopic and water soluble, and wherein greater than 80% of the hydroxide in the hydroxide-containing solid does not react with the carbon dioxide, and further wherein the alkali metal hydroxide-containing solid is substantially free of lithium hydroxide. A method of testing for the presence of carbonate-containing coating on an alkali metal hydroxide containing solid is also provided. The method includes exposing the coated solid to 95 weight percent ethanol, collecting the ethanol effluent and testing the effluent for alkali metal hydroxide. A suitably coated solid does not have dissolved alkali metal hydroxide in the ethanol effluent or is substantially free of alkali metal hydroxide.

A treatment liquid is a treatment liquid for a semiconductor device, which contains a fluorine-containing compound and a water-soluble aromatic compound not having a heterocyclic group but having a benzene ring, and has a pH of 5 or less.

A consumer product composition comprises a non-porous dissolvable solid structure comprising a carrier material, and hydrophobic conditioning agent and particulate spacer material disposed within the carrier material, wherein the hydrophobic conditioning agent has a mean particle size of from about 1 m to about 500 m and the particulate spacer material has a mean particle size of from about 55 m to about 750 m.

A consumer product composition comprises a non-porous dissolvable solid structure comprising a carrier material, and hydrophobic conditioning agent and particulate spacer material disposed within the carrier material, wherein the hydrophobic conditioning agent has a mean particle size of from about 1 m to about 500 m and the particulate spacer material has a mean particle size of from about 55 m to about 750 m.

A suctionable gel for eliminating a contaminating species contained in an organic layer on the surface of a material, consisting of a colloidal solution comprising, preferably consisting of: 1 wt % to 25 wt %, preferably 5 wt % to 20 wt % based on the total weight of the gel, of at least one inorganic viscosifying agent; 13 wt % to 99 wt %, preferably 80 wt % to 95 wt % based on the total weight of the gel, of an organic solvent selected among the terpenes and the mixtures thereof; optionally, 0.01 wt % to 10 wt %, based on the total weight of the gel, of at least one dye and/or pigment; optionally 0.1 wt % to 2 wt %, based on the total weight of the gel, of at least one surfactant. The disclosure further relates to a decontamination method using the gel.

This invention relates to a bleaching composition comprising hypochlorite-based bleach particles and moisture-sensitive particles encapsulating an oil within starch or starch-derivative matrix, the composition being surprisingly stable toward degradation of the starch upon storage.

The present invention provides a means capable of improving a residue removing effect and improving storage stability in a composition for surface treatment which is used for reducing residues on a surface of an object to be polished after being polished chemical mechanical polishing. The present invention relates to a composition for surface treatment, wherein the composition contains a solvent and a dissolved gas, a concentration of the dissolved gas is 0.01 mg/L or more and 10 mg/L or less with respect to a total volume of the composition and the composition is used for reducing residues on a surface of an object to be polished after being polished by chemical mechanical polishing.