Metallopolyimide precursor fibers for aging-resistant carbon molecular sieve hollow fiber membranes having enhanced selectivity include transition metal cations complexed with electronegative regions of a polyimide. CMS membranes are made by pyrolyzing the metallopolyimide precursor fibers. The cations are introduced by including, in the bore fluid used to extrude the fibers, either a salt of the transition metal and an inorganic anion or a transition metal/organic ligand complex.

Metallopolyimide precursor fibers for aging-resistant carbon molecular sieve hollow fiber membranes having enhanced selectivity include transition metal cations complexed with electronegative regions of a polyimide. CMS membranes are made by pyrolyzing the metallopolyimide precursor fibers. The cations are introduced by including, in the spin dope composition used to extrude the fibers, either a salt of the transition metal and an inorganic anion or a transition metal/organic ligand complex.

Metallopolyimide precursor fibers for aging-resistant carbon molecular sieve hollow fiber membranes having enhanced selectivity include transition metal cations complexed with electronegative regions of a polyimide. CMS membranes are made by pyrolyzing the metallopolyimide precursor fibers. The cations are introduced by including, in the spin dope composition used to extrude the fibers, either a salt of the transition metal and an inorganic anion or a transition metal/organic ligand complex.

Provided is an acidic gas-containing gas treatment separation membrane in which an intermediate layer provided on a support member is optimized, and which can treat and separate a gas mixture containing acidic gas and methane gas and/or nitrogen gas into the gas components, and thereby efficiently obtain acidic gas or methane gas and/or nitrogen gas. The acidic gas-containing gas treatment separation membrane includes an inorganic porous support member, an intermediate layer containing a polysiloxane network structure material and formed on a surface of the inorganic porous support member, and a separation layer containing a hydrocarbon group-containing polysiloxane network structure material and formed on the intermediate layer.

Provided is an interfacial polymerization process for preparation of a thin film composite membrane, which can be used for nanofiltration, forward osmosis, or reverse osmosis, particularly for use with brackish water or seawater. The process includes contacting a porous support membrane with an aqueous phase containing a polyamine to form a coated support membrane, and applying an organic phase containing a polyfunctional acyl halide to the coated support membrane to interfacially polymerize the polyamine and the polyfunctional acyl halide to form a discrimination layer of a thin film composite membrane, where during formation of the membrane, the polyfunctional acyl halide is purified in situ by removal of hydrolyzed acyl halide through addition of a salt rejection-enhancing additive that includes a biguanide compound, dicarbonate compound, pentathiodicarbonate compound, or salt thereof. Also provided are the membranes prepared by the methods and reverse osmosis modules containing the membranes.

The invention a solvent-resistant polymeric nanofiltration membrane and preparation method thereof. The method includes subjecting a diamine monomer and a dianhydride monomer to cyclization imidization in a first polar organic solvent at 160 to 230 C., to form a polyimide, wherein the diamine monomer includes a diamine monomer with a carboxyl group and a diamine monomer without a carboxyl group; dissolving the polyimide in a second polar organic solvent, to form a membrane-forming solution; performing phase inversion to obtain an intermediate membrane; treating the intermediate membrane with an organic solution of a metal salt, so that the metal ion is coordinated and cross-linked with the carboxyl group in the polyimide, to obtain a solvent-resistant polymeric nanofiltration membrane, wherein the metal salt is a divalent and/or a multi-valent metal salt. The invention also discloses use of the solvent-resistant polymeric nanofiltration membrane in the separation and/or purification of a compound.

The present disclosure provides extruded or spun, semi-permeable, porous hollow fibres, comprising covalent ester, thioester and/or amide crosslinked polypeptides as well as processes for their production. The hollow fibres may be produced from protein, protein extracts, and/or protein isolates derived from plants, animals, bacteria, algae, archaea, and/or fungi, and in certain embodiments are intended to be suitable for human and/or animal ingestion. In some embodiments, the hollow fibres may be designed to be used in the production of cartridges that are compatible with existing and/or novel bioreactor platforms, for harbouring cell cultures in cultured meat production.

A method for preparing a light- and oxygen-permeable membrane includes: adding polyvinylidene fluoride (PVDF), an organic solvent, and a pore-forming agent successively to a container, stirring at 60 C. to 80 C. for 5 h to 7 h, and conducting vacuum deaeration to obtain a PVDF casting solution; adding polydimethylsiloxane (PDMS) and a curing agent successively to a container, thoroughly stirring at 20 C. to 25 C., and conducting static deaeration to obtain a PDMS casting solution; blade-coating the PVDF casting solution on a glass plate, rinsing the glass plate in a rinsing tank to remove the organic solvent and the pore-forming agent, and oven-drying the glass plate to obtain an initial membrane; and coating the PDMS casting solution on a back side of the initial membrane, placing the initial membrane at room temperature for 2 h to 4 h, and oven-drying the initial membrane to obtain the light- and oxygen-permeable membrane.

The present invention relates to a method for one-step regulation of a pore structure and surface properties of a silicon carbide (SiC) membrane. The method comprises: first, fully mixing SiC powder with a sintering aid, and then synergistically regulating a pore structure and surface wetting properties of a SiC membrane by controlling a molding pressure and a sintering condition. The amount of SiO.sub.2 generated by oxidation of SiC is controlled, and in situ reaction of SiO.sub.2 and the sintering aid is prompted to generate a neck connection, such that a sintering temperature of the SiC membrane can be reduced, and the strength and corrosion resistance properties of the SiC membrane can also be improved. The degree of sintering of the SiC membrane is effectively controlled by means of the regulation of the molding pressure and the sintering temperature. It is a simple method for one-step regulation of a pore structure and surface properties of a SiC membrane. The SiC membrane prepared has porosity adjustable in a range of 13% to 48% and a pore size adjustable in a range of 0.17 m to 1 m; and the SiC membrane has an initial dynamic water contact angle in a range of 12.01 to 66.8 and an underwater oil contact angle adjustable in a range of 120.3 to 155.1. The SiC membrane prepared has high bending strength and pure water permeation properties and show a broad application prospect in the field of oil-water separation and emulsion preparation.

The present disclosure provides a rigid self-supporting MXene separation membrane and a preparation method and use thereof, belonging to the technical field of membranes. In the present disclosure, a MXene material is mixed with an aluminum salt powder to conduct one-step membrane formation by hot-pressing. The pressure forms the powder into a membrane and imparts rigidity, enabling a self-supporting structure; the heating breaks an ionic bond of an inorganic metal salt to reach a molten ionic state, and free metal cations react with active oxygen-containing functional groups on the surface of the MXene to form new chemical bonds (such as an AlO bond); such a chemical bond has higher energy, achieving a desirable anti-swelling effect to improve the membrane stability. The separation membrane further has excellent conductivity and hydrophilicity.