Superhydrophobic membrane structures having a beneficial combination of throughput and a selectivity. The membrane structure can include a porous support substrate; and a membrane layer adherently disposed on and in contact with the porous support substrate. The membrane layer can include a nanoporous material having a superhydrophobic surface. The superhydrophobic surface can include a textured surface, and a modifying material disposed on the textured surface. Methods of making and using the membrane structures.

A membrane based process separates amines or organic acids from a solution containing at least one amine or at least one organic acid according to their hydrophobic properties. The more hydrophobic amine or organic acid passes the hydrophobic membrane into an acidic aqueous solution, thus selectively removing the amine or organic acid from the first solution. The process is particularly suitable to obtain chiral amines in high yield. A transaminase-catalyzed transamination of an amino donor and amino acceptor is combined with a hydrophobic membrane separation of the produced chiral amine. The selective removal of the chiral amine from the reaction mixture promotes the further transformation of the amino acceptor into the product chiral amine.

Disclosed are a preparation method, a product and an application of a hydrophobically modified membrane based on multi-effect thermal energy conversion, the preparation method includes the steps: S1. dispersing carbon nanotubes with surfaces carboxylated in a solvent to form a dispersion; S2. applying the dispersion evenly on a PVDF membrane, and drying to form a ready-to-use membrane; S3. performing thermo-mechanical pressure treatment of the ready-to-use membrane to form a functional membrane with strong robustness; and S4. placing the functional membrane with strong robustness in an alkane solution of PDMS containing a silane coupling agent, and then taking it out for drying.

The present invention relates to a method for manufacturing a carbon membrane supported on a ceramic support. The present invention also relates to a carbon membrane prepared from hydroquinone on a ceramic tubular support and to the use of such a membrane. The present invention is focused on the preparation of carbon membranes from hydroquinone oligomer as a thermosetting precursor for gas separation. In an example chemical post treatment of membranes is used for increasing the H.sub.2/CO.sub.2, H.sub.2/N.sub.2 and CO.sub.2/N.sub.2 selectivities.

Disclosed herein are composite membranes comprising an omniphobic substrate having a reentrant structure. The omniphobic substrate comprises a plurality of pores, the plurality of pores forming the reentrant structure. The omniphobic substrate further comprises a surface, the surface being coated with a dual functional layer that is hydrophilic in air and oleophobic under water, such that the composite membrane has a top portion and a bottom portion, the top portion comprising the coated surface of the omniphobic substrate, such that the top portion of the composite membrane is hydrophilic in air and oleophobic under water and the bottom portion of the composite membrane is omniphobic. The composite membrane can be antiwetting and/or antifouling in the presence of a hydrophobic contaminant, an amphiphilic contaminant, or a combination thereof. The composite membranes can be used for membrane distillation of a contaminated brine solution.

A composite material is described that is an effective filter to separate oil from an oil and water emulsion or other mixtures of oil and water. The composite material has a permeable substrate, such as fabric, that is coated with a selectively-permeable coating. The composite material allows only oil to pass through, while water is prevented from passing through. The composite material has two main components, a hydrophobic component and an emulsion-destabilizing component.

A polymer having a contact angle with water that is greater than or equal to 90? and a contact angle with 1,3-propane diol that is less than 90?. A pervaporation membrane comprising the polymer and a process for purifying a fermentation broth using a pervaporation membrane comprising the polymer is also described.

An interfacial solar membrane includes a substrate with a coating of polypyrrole disposed on a surface of the substrate. The coating of polypyrrole is formed by dipping the substrate in a solution of pyrrole monomer and iron(III) chloride. The interfacial solar membrane can include a coating to improve a hydrophobicity of the interfacial solar membrane, such as a coating of 1H,1H,2H-perfluorooctyltriethoxysilane. A method of using the interfacial solar membrane includes using the interfacial solar membrane to evaporate a fluid and condensing the evaporated fluid to remove an impurity from the fluid.

The present invention relates to a method of preparing a decadodecasil 3R (DDR) type zeolite membrane and a membrane prepared thereby, and more particularly, to a method of preparing a hydrophobic decadodecasil 3R (DDR) type zeolite membrane having a continuous out-of-plane orientation by adding a substrate on which a seed layer is formed to a silica source synthetic precursor containing a methyltropinium salt and performing a hydrothermal synthesis, and a method of capturing and removing carbon dioxide using a membrane prepared thereby.

With the subject invention, a method is provided for preparing a filter membrane including the steps of dispersing a liquid which is generally hydrophobic into the pores of a porous membrane, and applying a solution containing lipids onto at least a first surface of the porous membrane containing the liquid. Advantageously, the subject invention allows for filter membranes to be prepared which can be stored for periods of time without degradation in performance. The subject invention may have applicability in various contexts, but is well-suited for preparing filter membranes for permeability screening, particularly Parallel Artificial Membrane Permeability Assay (PAMPA).