Abstract: A cell stack comprising an electrochemical cell, or a plurality of axially arranged electrochemical cells, with an end plate at each end of the stack, each cell comprising an active area surrounded by a peripheral area, wherein the active area comprises the membrane electrode assembly, and the peripheral area includes one or more channels for reactants, and wherein the stack comprises means for applying pressure axially to the active area to contact the membrane and electrodes, and separate means for applying pressure axially to the peripheral area. Further, a method of performing an electrochemical reaction in a cell comprising an active area surrounded by a peripheral area, comprises applying pressure to the active area, and varying the pressure during operation of the cell, wherein the active area includes the membrane electrode assembly and is the area where the cell reaction occurs.

Abstract: A composite cell plate can include a polymer element laterally mated and interlocked, at a plurality of engagement points, with a resilient metal element. The cell plate can be used in an electrochemical cell. A method of forming a cell plate can include fitting a polymer element to a resilient metal element at a plurality of engagement points, and expanding the polymer of the polymer element such that the polymer element and the resilient metal element engage and interlock at the engagement points.

Abstract: A cell stack comprising an electrochemical cell, or a plurality of axially arranged electrochemical cells, with an end plate at each end of the stack, each cell comprising an active area surrounded by a peripheral area, wherein the active area comprises the membrane electrode assembly, and the peripheral area includes one or more channels for reactants, and wherein the stack comprises means for applying pressure axially to the active area to contact the membrane and electrodes, and separate means for applying pressure axially to the peripheral area. Further, a method of performing an electrochemical reaction in a cell comprising an active area surrounded by a peripheral area, comprises applying pressure to the active area, and varying the pressure during operation of the cell, wherein the active area includes the membrane electrode assembly and is the area where the cell reaction occurs.

Abstract: A system for reducing pressure and extracting energy from natural gas pipelines or the cryogenics industry can include an electrolyzer that produces hydrogen, a heating device adapted to heat the natural gas in the pipeline, and a device adapted to extract energy from expansion of the natural gas. The extracted energy can be used to power the electrolyzer and/or heat the natural gas. The system can be used to extract energy from gas expansion.

Abstract: The present invention is the use of a compound comprising two or more covalently bonded polymerisable vinyl groups and one or more covalently bonded ionic groups selected from a quaternary ammonium group; a quaternary phosphonium group; or a tertiary sulphonium group, as an ionic cross-linker. The cross-linkers of the invention may be used to form an ionomer membrane. Methods for forming the cross-linkers of the invention are also disclosed.

Abstract: A method of forming a hydrophilic polymer is disclosed. The method can include: reacting a monomer comprising an acid group with a Bronsted base to form an ionic liquid; polymerizing the ionic liquid with at least one other monomer; and converting the ionic liquid back to the acid group after polymerization. Also disclosed are hydrophilic polymers and membrane electrode assemblies formed using the above method.

Abstract: The present invention is a hydrophilic polymer, which can be hydrated to form a hydrated hydrophilic polymer having a water content of at least 65%, wherein water content is defined as [(mass of the hydrated hydrophilic polymer?mass of the dry hydrophilic polymer)/mass of the hydrated hydrophilic polymer]×100. The hydrophilic polymer may be hydrated to form a hydrated hydrophilic polymer having a water content of at least 65%. The present invention also 10 provides MEAs and electrochemical cells and methods of forming same.

Abstract: A hydrophilic cross-linked polymer obtainable by copolymerisation of hydrophobic and hydrophilic monomers that give a cross-linked hydrophilic polymer on polymerisation; a monomer including a strongly ionic group; and water is useful as the membrane in an assembly that can be used in an electrolyter or fuel cell. More generally, a membrane electrode assembly comprises electrodes and an ion-exchange membrane which comprises a hydrophilic polymer including a strongly ionic group. A method for producing a membrane electrode assembly comprising electrodes and an ion-exchange membrane, comprises introducing between the electrodes a material or materials from which the membrane can be formed, and forming the membrane in situ.

Abstract: A membrane electrode assembly (MEA) comprises substantially concentric and tubular-shaped layers of a cathode, an anode and an ion-exchange membrane. The MEAs of the invention can be used in an electrochemical cell, which comprises the following layers which are tubular-shaped, arranged substantially concentrically, and listed from the inner layer to the outer layer; (i) a cylindrical core; (ii) one of the electrodes; (iii) a membrane; (iv) the other of the electrodes; and (v) an outer cylindrical sleeve.

Abstract: A composite cell plate can include a polymer element laterally mated and interlocked, at a plurality of engagement points, with a resilient metal element. The cell plate can be used in an electrochemical cell. A method of forming a cell plate can include fitting a polymer element to a resilient metal element at a plurality of engagement points, and expanding the polymer of the polymer element such that the polymer element and the resilient metal element engage and interlock at the engagement points.

Abstract: The present invention is the use of a compound comprising two or more covalently bonded polymerisable vinyl groups and one or more covalently bonded ionic groups selected from a quaternary ammonium group; a quaternary phosphonium group; or a tertiary sulphonium group, as an ionic cross-linker. The cross-linkers of the invention may be used to form an ionomer membrane. Methods for forming the cross-linkers of the invention are also disclosed.

Abstract: In a first aspect, a method for forming a ionic polymer membrane, comprises: (i) polymerising a mixture of one or more first monomers to form an ionic polymer membrane; (ii) soaking the polymer membrane of (i) into a mixture of one or more second monomers, for a sufficient length of time to allow the solution to penetrate through the entire polymer membrane; and (iii) polymerising the monomer-coated polymer of step (ii) to form an essentially homogenous ionic polymer. In a second aspect, a method for forming a catalyst-coated ionic polymer membrane, comprises: (i) polymerising a mixture of one or more first monomers to form an ionic polymer membrane; (ii) dipping the polymer of (i) into a mixture of one or more second monomers; (iia) depositing a catalyst onto the monomer-coated polymer; (iii) polymerising the monomer-coated polymer of step (iia). The present invention also includes membranes formed using these methods.

Abstract: A method of forming a catalyst ink is disclosed. The method can include: polymerising an ionic monomer and at least one non-ionic monomer to form a hydrophilic polymer; dissolving the hydrophilic polymer in a suitable solvent to form a polymer solution; and mixing a catalyst with the polymer solution to make a catalyst ink. Also disclosed are catalyst inks formed from this method, as well as membranes including the catalyst inks and methods for forming the same.

Abstract: A method of forming a hydrophilic polymer is disclosed. The method can include: reacting a monomer comprising an acid group with a Bronsted base to form an ionic liquid; polymerising the ionic liquid with at least one other monomer; and converting the ionic liquid back to the acid group after polymerisation. Also disclosed are hydrophilic polymers and membrane electrode assemblies formed using the above method.

Abstract: A method for determining information regarding an object comprising particles includes obtaining a wave function representative of the object detected at a detection surface of a detection system for detecting the wave function, deriving at least two spatial frequencies of the detected wave function, and deriving for each of the at least two spatial frequencies at least a phase based on the obtained wave function. A functional relationship between the spatial frequency and the phase is analyzed for the spatial frequencies. At least one parameter indicative of a property of the object is derived therefrom. A corresponding system involves the method as well as corresponding computer-related products.

Abstract: The present invention is a hydrophilic polymer, which can be hydrated to form a hydrated hydrophilic polymer having a water content of at least 65%, wherein water content is defined as [(mass of the hydrated hydrophilic polymer?mass of the dry hydrophilic polymer)/mass of the hydrated hydrophilic polymer]×100. The hydrophilic polymer may be hydrated to form a hydrated hydrophilic polymer having a water content of at least 65%. The present invention also 10 provides MEAs and electrochemical cells and methods of forming same.

Abstract: A method of performing an electrochemical reaction in an electrochemical cell comprising electrodes separated by a hydrophilic ion-exchange membrane, comprises conducting the reaction in the presence of an aqueous solution of an electrolyte of which the concentration is controlled.

Abstract: A cell stack comprising an electrochemical cell, or a plurality of axially arranged electrochemical cells, with an end plate at each end of the stack, each cell comprising an active area surrounded by a peripheral area, wherein the active area comprises the membrane electrode assembly, and the peripheral area includes one or more channels for reactants, and wherein the stack comprises means for applying pressure axially to the active area to contact the membrane and electrodes, and separate means for applying pressure axially to the peripheral area. Further, a method of performing an electrochemical reaction in a cell comprising an active area surrounded by a peripheral area, comprises applying pressure to the active area, and varying the pressure during operation of the cell, wherein the active area includes the membrane electrode assembly and is the area where the cell reaction occurs.

Abstract: In a method for the production of a membrane electrode assembly comprising a membrane, electrodes and a catalyst, the catalyst is pressed into the membrane material, e.g. when forming the material in situ.

Abstract: A membrane-electrode assembly includes a grid for controlling ion flow, separate layers of membrane material and/or an ionically inactive material for the transmission of a liquid or gaseous reaction component to end/or form at least one of the electrodes.