A polymer composition comprising a covalent triazine framework having the following structure:

##STR00001##

wherein: each asterisk (*) in A units denotes a point of covalent bonding with an asterisk in B units, and each asterisk (*) in B units denotes a point of covalent bonding with an asterisk in A units; r is an integer of 1-3; R is a fluorinated hydrocarbon containing at least two aromatic rings and at least one ether linkage between aromatic rings; the composition includes a multiplicity of A units and multiplicity of B units; and a portion of the connection points are terminated by endcapping nitrile groups. Also described are methods for producing the polymer and a microporous carbon material produced by pyrolysis of the porous polymer membrane. Also described are methods for using the polymer and microporous carbon material for gas or liquid separation, filtration, or purification.

A polymer composition comprising a covalent triazine framework having the following structure:

##STR00001##

wherein: each asterisk (*) in A units denotes a point of covalent bonding with an asterisk in B units, and each asterisk (*) in B units denotes a point of covalent bonding with an asterisk in A units; r is an integer of 1-3; R is a fluorinated hydrocarbon containing at least two aromatic rings and at least one ether linkage between aromatic rings; the composition includes a multiplicity of A units and multiplicity of B units; and a portion of the connection points are terminated by endcapping nitrile groups. Also described are methods for producing the polymer and a microporous carbon material produced by pyrolysis of the porous polymer membrane. Also described are methods for using the polymer and microporous carbon material for gas or liquid separation, filtration, or purification.

Polymers of intrinsic microporosity are provided herein. Disclosed polymers of intrinsic microporosity include modified polymers of intrinsic microporosity that include negatively charged sites or crosslinking between monomer units. Systems making use of polymers of intrinsic microporosity and modified polymers of intrinsic microporosity are also described, such as electrochemical cells and ion separation systems. Methods for making and using polymers of intrinsic microporosity and modified polymers of intrinsic microporosity are also disclosed.

Polymers of intrinsic microporosity are provided herein. Disclosed polymers of intrinsic microporosity include modified polymers of intrinsic microporosity that include negatively charged sites or crosslinking between monomer units. Systems making use of polymers of intrinsic microporosity and modified polymers of intrinsic microporosity are also described, such as electrochemical cells and ion separation systems. Methods for making and using polymers of intrinsic microporosity and modified polymers of intrinsic microporosity are also disclosed.

The invention provides: imidazole and imidazolium compounds of formulas (I) and (II):

##STR00001##

polymers containing a plurality of imidazolium-containing repeating units of formula (III′):

##STR00002##

and membranes and devices comprising the polymers. Also provided are methods of making the inventive compounds and polymers.

The invention provides: imidazole and imidazolium compounds of formulas (I) and (II):

##STR00001##

polymers containing a plurality of imidazolium-containing repeating units of formula (III′):

##STR00002##

and membranes and devices comprising the polymers. Also provided are methods of making the inventive compounds and polymers.

A crosslinkable copolymer is provided. The crosslinkable copolymer has pendant cationic nitrogen-containing groups with some, but not all, of these pendant groups further including a (meth)acryloyl group. The (meth)acryloyl groups can react to form a crosslinked copolymer that is ionically conductive. The crosslinked copolymer can be used to provide an anion exchange membrane that can be used in electrochemical cells such as fuel cells, electrolyzers, batteries, and electrodialysis cells.

This disclosure relates to CO.sub.2-philic crosslinked polyethylene glycol membranes useful for natural gas purification processes. Also provided are methods of using the membranes to remove CO.sub.2 and H.sub.2S from natural gas.

A gas separation membrane, methods of forming the membrane, and methods of using the membrane for gas separation are provided. An exemplary gas separation membrane includes a cellulosic matrix and a polymer of intrinsic microporosity (PIM). The PIM includes chains coupled by a heat-treating under vacuum.

A gas separation membrane, methods of forming the membrane, and methods of using the membrane for gas separation are provided. An exemplary gas separation membrane includes a cellulosic matrix and a polymer of intrinsic microporosity (PIM). The PIM includes chains coupled by a heat-treating under vacuum.