Abstract: The invention provides a method for producing sheet-like particles of zeolite that cannot be obtained by a top-down method, and provides sheet-like particles of zeolite having an 8-membered oxygen ring structure obtained by the method. A thickness of the sheet-like particles is 1 nm to 100 nm, and an aspect ratio (maximum width/thickness in particles) of the sheet-like particles is 100 or more.

Abstract: The invention provides a method for producing sheet-like particles of zeolite that cannot be obtained by a top-down method, and provides sheet-like particles of zeolite having an 8-membered oxygen ring structure obtained by the method. A thickness of the sheet-like particles is 1 nm to 100 nm, and an aspect ratio (maximum width/thickness in particles) of the sheet-like particles is 100 or more.

Abstract: The present disclosure provides a method for producing a metal organic framework nanosheet, including forming a metal organic framework in a sheet form between two monolayers constituting a single bilayer membrane in a case where the bilayer membranes form a hyper-swollen lamellar phase in a solvent. The present disclosure relates to a metal organic framework nanosheet including a metal organic framework disposed, in a sheet form, between two monolayers constituting a single bilayer membrane, wherein a plurality of the bilayer membranes forms a hyper-swollen lamellar phase in a solvent.

Abstract: The present disclosure provides a method for producing a metal organic framework nanosheet, including forming a metal organic framework in a sheet form between two monolayers constituting a single bilayer membrane in a case where the bilayer membranes form a hyper-swollen lamellar phase in a solvent. The present disclosure relates to a metal organic framework nanosheet including a metal organic framework disposed, in a sheet form, between two monolayers constituting a single bilayer membrane, wherein a plurality of the bilayer membranes forms a hyper-swollen lamellar phase in a solvent.

Abstract: This invention relates to a method wherein a high-purity paraxylene can be produced efficiently by using a catalyst having a molecular sieving action (or shape selectivity) and being excellent in the catalytic activity without isomerization and adsorption-separation steps. More particularly, it relates to a method of producing a high-purity paraxylene, characterized in that MFI type zeolite having a primary particle size of not more than 100 ?m, a structure defining agent and silica material having an average particle size of not less than 10 nm but less than 1.0 ?m are used as a starting material, and a synthetic zeolite catalyst produced by subjecting the MFI type zeolite to a coating treatment with an aqueous solution obtained by mixing so as to satisfy X×Y<0.05 (wherein X is a concentration of the silica material (mol %) and Y is a concentration of the structure defining agent (mol %)) is used in the alkylation or disproportionation of at least one of benzene and toluene as a starting material.

Abstract: This invention relates to a method wherein a high-purity paraxylene can be produced efficiently by using a catalyst having a molecular sieving action (or shape selectivity) and being excellent in the catalytic activity without isomerization and adsorption-separation steps. More particularly, it relates to a method of producing a high-purity paraxylene, characterized in that MFI type zeolite having a primary particle size of not more than 100 ?m, a structure defining agent and silica material having an average particle size of not less than 10 nm but less than 1.0 ?m are used as a starting material, and a synthetic zeolite catalyst produced by subjecting the MFI type zeolite to a coating treatment with an aqueous solution obtained by mixing so as to satisfy X×Y<0.05 (wherein X is a concentration of the silica material (mol %) and Y is a concentration of the structure defining agent (mol %)) is used in the alkylation or disproportionation of at least one of benzene and toluene as a starting material.

Abstract: An electroconductive porous film high in the porosity and strong in the mechanical strength is provided. A mesoporous thin film of the invention, in which a crosslinking structure having a metal phosphate (M—POx) skeleton is arranged so as to surround periodically arranged pores, is formed by use of a process that includes: a step of preparing a precursor solution containing phosphoric acid and a surfactant; a step of supplying the precursor solution to a substrate to form a precursor thin film; a step of bringing vapor containing a metal into contact with the precursor thin film obtained in the forming the thin film; a step of reacting the vapor containing a metal and phosphoric acid to form a self-organized thin film; and a step of removing the surfactant from the self-organized thin film.

Abstract: A tungsten-containing mesoporous silica thin film, which is a mesoporous silica thin film formed from a solution containing a silica precursor and a water-soluble tungsten compound, and has a molar ratio (W/Si) of tungsten content to silicon content of 0.001 to 0.04, a film thickness of 0.1 to 5 ?m, and an average pore diameter of 20 nm or less.

Abstract: The proton-conductive film comprises a mesoporous thin film that has, as the principal component thereof, a crosslinked structure having a metal-oxygen skeleton with an acid group bonding to at least a part thereof, in which the pores are periodically aligned and the inner wall of the pores is coated with a silanol group.

Abstract: An electroconductive porous film high in the porosity and strong in the mechanical strength is provided. A mesoporous thin film of the invention, in which a crosslinking structure having a metal phosphate (M—POx) skeleton is arranged so as to surround periodically arranged pores, is formed by use of a process that includes: a step of preparing a precursor solution containing phosphoric acid and a surfactant; a step of supplying the precursor solution to a substrate to form a precursor thin film; a step of bringing vapor containing a metal into contact with the precursor thin film obtained in the forming the thin film; a step of reacting the vapor containing a metal and phosphoric acid to form a self-organized thin film; and a step of removing the surfactant from the self-organized thin film.

Abstract: The invention is characterized by attaining a lower dielectric constant and including an inorganic dielectric film which is formed on the surface of a substrate and has a cyclic porous structure having a pore ratio of 50% or higher.

Abstract: There is included an inorganic insulating film having a porous structure including a cylindrical vacancy oriented in parallel with the surface of a substrate subjected to a hydrophilic treatment or a hydrophobic treatment.

Abstract: There is included an inorganic insulating film having a porous structure including a cylindrical vacancy oriented in parallel with the surface of a substrate subjected to a hydrophilic treatment or a hydrophobic treatment.

Abstract: The proton-conductive film comprises a mesoporous thin film that has, as the principal component thereof, a crosslinked structure having a metal-oxygen skeleton with an acid group bonding to at least a part thereof, in which the pores are periodically aligned and the inner wall of the pores is coated with a silanol group.

Abstract: The invention aims at providing a dielectric film having a low dielectric constant and enhanced mechanical strength. A surfactant and an silica derivative are dissolved into a solvent at a desired mole ratio. The precursor solution is applied over the substrate, and the substrate is exposed to a silica derivative atmosphere before being sintered, thereby supplying a silica derivative. Thus, contraction of the film stemming from hydrolysis is inhibited, and a sturdy mesoporous silica thin film which takes the self-assembly of the surfactant as a mold is obtained while cavities are maintained intact without being fractured. Thus, there is formed an inorganic dielectric film which is formed on the surface of the substrate and has a cyclic porous structure including layered or columnar pores oriented so as to become parallel with the surface of the substrate.

Abstract: An object of the present invention is to provide a stable protonically-conductive membrane for fuel cell having a high reliability. Another object of the present invention is to provide a high efficiency fuel cell having a high mechanical strength which operates over an extended period of time. The protonically-conductive membrane (ionically-conductive membrane) of the present invention is formed by a mesoporous thin film comprising as a main component a crosslinked structure having a metal-oxygen skeleton having an acid group connected to at least a part thereof and having pores (3) periodically aligned therein.

Abstract: It is an object to provide, with a high productivity, a dielectric thin film having a high degree of pore and a very great mechanical strength, and there are included a surfactant film forming step of forming a film including a surfactant on a surface of a substrate on which a thin film is to be formed, a vapor deposition step of causing the substrate to come in contact with a gas phase containing a silica derivative to form a thin film including the silica derivative, and a step of calcining the substrate having the thin film formed thereon and decomposing and removing the surfactant, the thin film being thus formed.

Abstract: The invention is characterized by attaining a lower dielectric constant and including an inorganic dielectric film which is formed on the surface of a substrate and has a cyclic porous structure having a pore ratio of 50% or higher.

Abstract: The invention is characterized by attaining a lower dielectric constant and including an inorganic dielectric film which is formed on the surface of a substrate and has a cyclic porous structure having a pore ratio of 50% or higher.

Abstract: A mesoporous silica is provided, having uniform mesopores and a periodic structure, which contains Zr in the form of a Si—O—Zr bond. The Zr content in the Si—O—Zr bond, represented by [Zr/(Si+Zr)], is 0.05 to 20 mole %. The mesoporous silica is superior in alkaline resistance and is suitably used as a separation membrane (e.g. a ceramic membrane) and a catalytic support for a solid-liquid system, in which an alkaline liquid may be used.