The present invention is related to formation and processing of antiperovskite material. In various embodiments, a thin film of aluminum doped antiperovskite is deposited on a substrate, which can be an electrolyte material of a lithium-based electrochemical storage device.

This application pertains to methods of recovering metals from metal sulfides that involve contacting the metal sulfide with an acidic sulfate solution containing ferric sulfate and a reagent that has a thiocarbonyl functional group, wherein the concentration of reagent in the acidic sulfate solution is sufficient to increase the rate of metal ion extraction relative to an acidic sulfate solution that does not contain the reagent, to produce a pregnant solution containing the metal ions.

This disclosure relates to porous carbon and a method of preparing the same. The porous carbon of the present invention is derived from a carbide compound having a composition comprising metal and oxide. The porous carbon of the present invention comprises both micropores and mesopores, and has large specific surface area, and thus, may be usefully used in various fields.

This disclosure relates to porous carbon and a method of preparing the same. The porous carbon of the present invention is derived from a carbide compound having a composition comprising metal and oxide. The porous carbon of the present invention comprises both micropores and mesopores, and has large specific surface area, and thus, may be usefully used in various fields.

A process for dewatering oil sand fine tailings is provided and comprises a dispersion and floc build-up stage comprising in-line addition of a flocculent solution comprising an effective amount of flocculation reagent into a flow of the oil sand fine tailings; a gel stage wherein flocculated oil sand fine tailings is transported in-line and subjected to shear conditioning; a floc breakdown and water release stage wherein the flocculated oil sand fine tailings releases water and decreases in yield shear stress, while avoiding an oversheared zone; depositing the flocculated oil sand fine tailings onto a deposition area to form a deposit and to enable the release water to flow away from the deposit, preferably done in a pipeline reactor and managing shear according to yield stress and CST information and achieves enhanced dewatering.

The disclosure provides relates to compositions and methods for water treatment. It also addresses a method for synthesizing TiO.sub.2 (and other metal oxides) with or without dopants. This method enables control over size, phase, morphology and porosity and specific surface area of these materials. The disclosure also provides metal oxide composites that can be used in photocatalysts, photovoltaics, and solar hydrogen applications.

The disclosure provides relates to compositions and methods for water treatment. It also addresses a method for synthesizing TiO.sub.2 (and other metal oxides) with or without dopants. This method enables control over size, phase, morphology and porosity and specific surface area of these materials. The disclosure also provides metal oxide composites that can be used in photocatalysts, photovoltaics, and solar hydrogen applications.

The disclosure provides relates to compositions and methods for water treatment. It also addresses a method for synthesizing TiO.sub.2 (and other metal oxides) with or without dopants. This method enables control over size, phase, morphology and porosity and specific surface area of these materials. The disclosure also provides metal oxide composites that can be used in photocatalysts, photovoltaics, and solar hydrogen applications.

The subject matter herein provides a biotic method for recovering one or more hydrocarbons from a feedstock that includes one or more of oil shale, bituminous tar sand, coal and cellulous at atmospheric temperature and pressure. The method comprises loading the feedstock into a container, treating the feedstock in the container with a biomedium of micro-organisms, and forming an essentially liquid mixture from the feedstock and the biomass by rotary tumbling the feedstock and the biomedium in the container. The essentially liquid mixture is then separated into the one or more hydrocarbons by centrifuging.

A method for preparing a -Ga.sub.2O.sub.3 nanomaterial, comprising a step of treating a mixture comprising a gallium element, water, and an organic solvent with ultrasound. The preparation process and equipment requirements are simple, the cost of materials is low, there are fewer experimental parameters, and experimental conditions are mild, with no additional heat source and/or pressure being applied. The -Ga.sub.2O.sub.3 nanomaterial can be prepared, in kilograms or above, quickly at an ambient temperature and pressure.