Provided is halloysite powder having a small b value. The halloysite powder is powder including a granule in which halloysite including halloysite nanotubes is aggregated, the granule has a first pore deriving from a tube hole of the halloysite nanotubes and a second pore different from the first pore, and the Fe.sub.2O.sub.3 content is not more than 2.00 mass %.

Provided is halloysite powder having a small b value. The halloysite powder is powder including a granule in which halloysite including halloysite nanotubes is aggregated, the granule has a first pore deriving from a tube hole of the halloysite nanotubes and a second pore different from the first pore, and the Fe.sub.2O.sub.3 content is not more than 2.00 mass %.

A high-purity artificial zeolite is industrially mass produced by carrying out osmosis treatment of fly ash in an alkaline aqueous solution, subsequently carrying out the osmosis treatment again with an acidic aqueous solution of pH 1.0 or less obtained by adding acid to the osmotic aqueous solution of fly ash, then performing solid-liquid separation while water wash and dewatering in a centrifuge, thereby synthesizing a starting composition, and performing hydrothermal reaction treatment to this starting composition.

Porous compositions and methods of making and using same. The compositions may be one or more layer(s) of mesoporous inorganic materials. The mesoporous inorganic material(s) may be a plurality of inorganic nanocages, which may be microporous. A composition may include homostacks of layers of the same inorganic mesoporous materials. A composition may include heterostacks of layers of inorganic mesoporous materials, where at least two of the layers are different. The compositions may be surface functionalized. The compositions may be formed in a reaction mixture including one or more precursor(s), one or more surfactant(s), water, and one or more organic solvent(s). The compositions may be formed at the liquid-liquid interface between the water and the one or more organic solvent(s). A composition may be used as a catalyst, in a catalytic method, as a separation medium, in a separation method, in nanomedicine applications, or the like.

Porous compositions and methods of making and using same. The compositions may be one or more layer(s) of mesoporous inorganic materials. The mesoporous inorganic material(s) may be a plurality of inorganic nanocages, which may be microporous. A composition may include homostacks of layers of the same inorganic mesoporous materials. A composition may include heterostacks of layers of inorganic mesoporous materials, where at least two of the layers are different. The compositions may be surface functionalized. The compositions may be formed in a reaction mixture including one or more precursor(s), one or more surfactant(s), water, and one or more organic solvent(s). The compositions may be formed at the liquid-liquid interface between the water and the one or more organic solvent(s). A composition may be used as a catalyst, in a catalytic method, as a separation medium, in a separation method, in nanomedicine applications, or the like.

A ferrosilicate molecular sieve having the framework structure of SSZ-70 and a method of making the same is disclosed. The ferrosilicate molecular sieve can be used in processes for dewaxing paraffinic hydrocarbon feedstocks.

A zeolitic material having the ITH framework structure type.A process for the preparation of a zeolitic material having the ITH framework structure type, the process comprising: (1) preparing a mixture comprising one or more specific organotemplates as structure direct-ing agents, one or more sources of YO2, optionally one or more sources of X2O3, seed crystals, and a solvent system, wherein Y is tetravalent element and X is a trivalent ele-ment,(2) heating the mixture obtained in (1) for crystallizing a zeolitic material having the ITH framework structure type comprising YO2 and optionally X2O3 in its framework structure; wherein the one or more organotemplates comprise a specific polymeric cation.

This invention relates to treated geothermal brine compositions containing reduced concentrations of lithium, iron and silica compared to the untreated brines. Exemplary compositions contain concentration of lithium ranges from 0 to 200 mg/kg, concentration of silica ranges from 0 to 30 mg/kg, concentration of iron ranges from 0 to 300 mg/kg. Exemplary compositions also contain reduced concentrations of elements like arsenic, barium, and lead.

This invention relates to treated geothermal brine compositions containing reduced concentrations of lithium, iron and silica compared to the untreated brines. Exemplary compositions contain concentration of lithium ranges from 0 to 200 mg/kg, concentration of silica ranges from 0 to 30 mg/kg, concentration of iron ranges from 0 to 300 mg/kg. Exemplary compositions also contain reduced concentrations of elements like arsenic, barium, and lead.

A coated particle having excellent thermal expansion control and electrical insulation properties includes a core of a first inorganic compound containing a metal or semimetal element P; and a shell of a second inorganic compound containing a metal or semimetal element Q. The first inorganic compound satisfies 1, and the coated particles satisfy 2 and 3. 1: |dA(T)/dT| is ≥10 ppm/°C at T1 of -200° C. to 1,200° C. A is (an a-axis lattice constant of a crystal in the first inorganic compound)/(a c-axis lattice constant of a crystal in the first inorganic compound). 2: in XPS of a surface of each of the coated particles, a ratio of a number of atoms of Q contained in the shell to a number of atoms of P contained in the core t is 45 to 300. 3: an average particle diameter of each coated particle is 0.1 to 100 .Math.m.