A process for the preparation of a filtration membrane, which includes providing an aqueous suspension of vesicles having transmembrane proteins incorporated therein, the vesicles being formed from an amphiphilic block copolymer having reactive end groups; providing a porous support; functionalizing a surface of the porous support to introduce reactive groups on the surface which are capable of reacting with the reactive end groups of the amphiphilic block copolymers of the vesicles; depositing said suspension of vesicles on a surface of the porous support; and providing reaction conditions such that covalent bonds are formed between the vesicles and the surface.

A process for the preparation of a filtration membrane, which includes providing an aqueous suspension of vesicles having transmembrane proteins incorporated therein, the vesicles being formed from an amphiphilic block copolymer having reactive end groups; providing a porous support; functionalizing a surface of the porous support to introduce reactive groups on the surface which are capable of reacting with the reactive end groups of the amphiphilic block copolymers of the vesicles; depositing said suspension of vesicles on a surface of the porous support; and providing reaction conditions such that covalent bonds are formed between the vesicles and the surface.

Disclosed herein is a method of preparing a nanoporous organic-inorganic hybrid film. The method includes preparing an organic sol including a compound having amino groups, a compound having isocyanate groups, and a solvent; adding an inorganic oxide precursor to the organic sol to form a mixed solution; and subjecting the mixed solution to heat treatment to form an organic molecule network structure in which the organic sol is gelled, and an inorganic molecule network structure located along a surface of the organic molecule network structure.

Disclosed is a 1D nanofibers quasi-aligned, grid structure cross-laminated, and pore distribution and size controlled 3D polymer nanofiber membrane, and manufacturing method thereof. A 3D polymer nanofiber membrane controlled in pore size and porosity is formed by employing an electrospinning pattern forming apparatus that includes double insulating blocks quasi-aligns nanofibers in a specific direction by transforming an electric field and includes a current collector rotatable in 90. Additionally, the 3D polymer nanofiber membrane may be used for air filters, separator, water filters, cell culture membranes, and so on by allowing various properties thereto through a functional surface coating.

Disclosed is a 1D nanofibers quasi-aligned, grid structure cross-laminated, and pore distribution and size controlled 3D polymer nanofiber membrane, and manufacturing method thereof. A 3D polymer nanofiber membrane controlled in pore size and porosity is formed by employing an electrospinning pattern forming apparatus that includes double insulating blocks quasi-aligns nanofibers in a specific direction by transforming an electric field and includes a current collector rotatable in 90. Additionally, the 3D polymer nanofiber membrane may be used for air filters, separator, water filters, cell culture membranes, and so on by allowing various properties thereto through a functional surface coating.

Disclosed herein are aspects and embodiments of hydrophilic polymeric blend and polymeric membranes which may be formed from the hydrophilic polymeric blend. In one example, the polymeric blend includes a hydrophobic membrane forming polymer and a polyoxazoline as a blend compatible hydrophilizing additive.

A membrane, in which the membrane is an ultrapure water membrane; a food and/or beverage processing membrane; a municipal water membrane; a peel oil recovery membrane; a (bio) refinery dewatering membrane; an oily wastewater (pre-)treatment membrane; a metal extraction membrane; a desalination membrane; and/or a protein fraction membrane. The membrane includes a porous substrate layer and an active layer arranged over at least a part of the substrate layer. The active layer is at least partially crosslinked and comprises a superhydrophilic agent. Also described is a method of producing the separation membrane.

A membrane, in which the membrane is an ultrapure water membrane; a food and/or beverage processing membrane; a municipal water membrane; a peel oil recovery membrane; a (bio) refinery dewatering membrane; an oily wastewater (pre-)treatment membrane; a metal extraction membrane; a desalination membrane; and/or a protein fraction membrane. The membrane includes a porous substrate layer and an active layer arranged over at least a part of the substrate layer. The active layer is at least partially crosslinked and comprises a superhydrophilic agent. Also described is a method of producing the separation membrane.

The present invention provides a separation membrane suitable for suppressing variation in separation performance. A separation membrane 10 of the present invention includes a separation functional layer 1, a porous support member 3 supporting the separation functional layer 1, and an intermediate layer 2 that is disposed between the separation functional layer 1 and the porous support member 3 and is formed from an emulsion resin composition. The emulsion resin composition includes, for example, a silicone-based polymer, a hydrophilic polymer, etc.

A method of synthesizing a mixed matrix membrane (MMM) film. The method includes: synthesizing a polymer including a polynorbornene or a polytricyclononene; synthesizing covalent-triazine frameworks (CTFs); preparing a polymer solution by dissolving the polymer in a first solvent; preparing a filler solution by dispersing the CTFs in a second solvent; adding the polymer solution to the filler solution while stirring the filler solution, forming a casting solution; pouring the casting solution into a membrane support; and drying the poured casting solution in the membrane support to form the MMM film including the CTFs.