A non crosslinked, covalently crosslinked and/or ionically crosslinked polymer, having repeating units of the general formula (1)
KR(1)
In which K is a bond, oxygen, sulfur, ##STR00001##
the radical R is a divalent radical of an aromatic or heteroaromatic compound.

A non crosslinked, covalently crosslinked and/or ionically crosslinked polymer, having repeating units of the general formula (1)
KR(1)
In which K is a bond, oxygen, sulfur, ##STR00001##
the radical R is a divalent radical of an aromatic or heteroaromatic compound.

Embodiments of the invention relate to methods and equipment to make lithium hydroxide from lithium salts.

Embodiments of the invention relate to methods and equipment to make lithium hydroxide from lithium salts.

An ion exchange system includes a first ion exchange column containing a first resin having an affinity for sulfate ions and nitrate ions that is greater than the first resin's affinity for chloride ions. The first ion exchange column is configured to pass a predetermined mass flow rate of drainage water therethrough. A second ion exchange column is connected in series with the first ion exchange column. The second ion exchange column contains a second resin having an affinity for chloride ions and is configured to pass the same predetermined mass flow rate of the same drainage water therethrough. As the drainage water passes through the first ion exchange column, primarily sulfate ions and/or nitrate ions are removed from the drainage water. As the drainage water passes through the second ion exchange column, primarily chloride ions are removed from the drainage water.

An ion exchange system includes a first ion exchange column containing a first resin having an affinity for sulfate ions and nitrate ions that is greater than the first resin's affinity for chloride ions. The first ion exchange column is configured to pass a predetermined mass flow rate of drainage water therethrough. A second ion exchange column is connected in series with the first ion exchange column. The second ion exchange column contains a second resin having an affinity for chloride ions and is configured to pass the same predetermined mass flow rate of the same drainage water therethrough. As the drainage water passes through the first ion exchange column, primarily sulfate ions and/or nitrate ions are removed from the drainage water. As the drainage water passes through the second ion exchange column, primarily chloride ions are removed from the drainage water.

An electrochemical device includes an anode, a cathode, and a separator interposed between the anode and cathode. The separator includes an anion conductive membrane having a porous substrate having hydrophilic moieties bonded thereto to increase water availability in a vicinity of ionogenic sites contributing to conductivity of the membrane in a presence of aqueous phases imbibed therein.

A method for producing a polymer of the present invention includes the following steps (a) and (b): step (a): producing a polymer in the presence of an acid or base catalyst; and step (b): contacting a solution containing the polymer obtained in step (a) to a mixed resin of an anion-exchange resin and a cation-exchange resin.

A method for producing a polymer of the present invention includes the following steps (a) and (b): step (a): producing a polymer in the presence of an acid or base catalyst; and step (b): contacting a solution containing the polymer obtained in step (a) to a mixed resin of an anion-exchange resin and a cation-exchange resin.

Disclosed herein are embodiments of compositions comprising polyols and cationic group-functionalized polyphenylene polymers suitable for use in electrochemical systems. The disclosed composition exhibit improved dispersion properties and further provide anion exchange polymer membranes exhibited improved chemical and mechanical properties. Also disclosed herein are methods of making and using the disclosed compositions.