The present invention relates to a porous organic polymer-based hydrogen ion conductive material and a method for preparing the same. More specifically, the present invention relates to a method for preparing a porous organic polymer (POP)-based material with high proton conductivity that is applicable to a membrane electrode assembly (MEA) of a proton exchange membrane fuel cell (PEMFC). The porous organic polymer-based proton conductive material of the present invention can be prepared in an easy and simple manner by microwave treatment and acid treatment requiring short processing time and low processing cost. In addition, the porous organic polymer-based proton conductive material of the present invention can be developed into a highly proton conductive material having the potential to replace Nafion through a simple post-synthesis modification. Therefore, the porous organic polymer-based proton conductive material of the present invention is suitable for use in a proton exchange membrane fuel cell.

An interpenetrating network (IPN) polymer membrane material includes a soft polyurethane interspersed with a crosslinked conducting polymer. The material can be reversibly “switched” between its oxidized and reduced states by the application of a small voltage, ˜1 to 4 volts, thus modulating its diffusivity.

An interpenetrating network (IPN) polymer membrane material includes a soft polyurethane interspersed with a crosslinked conducting polymer. The material can be reversibly “switched” between its oxidized and reduced states by the application of a small voltage, ˜1 to 4 volts, thus modulating its diffusivity.

An interpenetrating network (IPN) polymer membrane material includes a soft polyurethane interspersed with a crosslinked conducting polymer. The material can be reversibly “switched” between its oxidized and reduced states by the application of a small voltage, ˜1 to 4 volts, thus modulating its diffusivity.

Biocompatible polymer hydrogel composite structures, methods of making the composite structures, and methods of using the composite structures as scaffolds for biological tissue growth and regeneration are provided. The methods for making the composite structures start with a porous high resolution three-dimensional hydrogel scaffold in which polymer precursors are infused and then polymerized in situ to form a water-soluble, electrically conducting polymer that is bonded to and/or entrapped within the hydrogel.

Conjugated, electrically conducting polymers (CPs) with the ability to covalently graft onto collagen and collagenic materials are provided. Also provided are methods of functionalizing biological tissues and other biological substrates with the CPs, and methods of using the functionalized biological substrates as cell and tissue growth scaffolds that harness the passive therapeutic benefits of CPs and use the enhanced conductivity provided by the scaffolds to stimulate cell growth and proliferation through the bulk of the biological substrate.

The present invention relates to (i) a method of producing a conductive polymer, comprising polymerizing at least one of compounds (A1) represented by the formula (1) disclosed in the specification in the presence of a compound (B) having sulfo group; (ii) a method of producing a conductive polymer, comprising polymerizing at least one compound selected from a group consisting of at least one compound (A2) represented by the formula (2); and (iii) a method of producing a conductive polymer, comprising copolymerizing at least one compound (A1) and at least one compound selected from a group consisting of at least one compound (A2). The method of the present invention is a method for producing a one-liquid type conductive polymer in which it is possible to easily adjust the solvent affinity, the solubility, and other such aspects of performance according to the purpose.

Provided is a charge transporting composition that gives a charge transporting thin film having high transparency and excellent flatness. Also provided is an organic EL device that exhibits excellent characteristics.

A charge transporting thin film prepared using a composition containing a polythiophene compound, metal oxide nanoparticles, a nonionic fluorine-containing surfactant and an organic solvent has high transparency and excellent flatness, and use of the charge transporting thin film as a hole injection layer allows an organic EL device having excellent characteristics to be obtained.

Poly(sulfonic acid)s including a multiplicity of sulfonic acid units separated by alkylene units in a polymer chain or a copolymer chain, the poly(sulfonic acid) having a degree of crosslinking in a range of from about 0.1 to about 30 percent. Methods of preparing poly(sulfonic acid)s having improved mechanical integrity. The methods may include synthesizing a poly(sulfonic acid) by acyclic diene metathesis (ADMET) polymerization and reacting a plurality of double bonds afforded by the ADMET polymerization with a crosslinker. The crosslinking reaction may achieve a degree of crosslinking in a range of from about 0.1 to about 30 percent.

An onium salt of arenesulfonic acid having a bridged ring-containing group generates a bulky acid having an appropriate strength and controlled diffusion. When a positive resist composition comprising the onium salt and a base polymer is processed by lithography, a pattern of rectangular profile having high resolution and reduced LER is formed.