Abstract: Nickel electrodes having high mechanical stability and advantageous electrochemical properties, in particular, enhanced gas evolution in water electrolysis, are described. These electrodes comprising electrically conductive nickel wire mesh or a lattice-like nickel expanded metal webs, and a layer of mutually adherent nanoporous nickel particles applied only to either the nickel mesh wires or the nickel expanded metal webs, obtainable by partially reducing the spherical nickel hydroxide particles in a reducing atmosphere between 270 to 330° C. to obtain partially reduced, spherical Ni/NiO particles, producing a paste from the Ni/NiO particles, an organic and/or inorganic binder, a surfactant and, optionally, additional adjuvants, applying the paste as a coating to the electrically conductive nickel mesh or nickel expanded metal, and annealing the coated nickel mesh or nickel expanded metal in a reducing atmosphere at 500 to 800° C. A method for manufacturing the nickel electrode is also described.

Abstract: The invention relates to a reversible manganese dioxide electrode, comprising an electrically conductive carrier material having a nickel surface, a nickel layer made of spherical nickel particles adhering to each other and having an inner pore structure applied to the carrier material, and a manganese dioxide layer applied to the nickel particles, wherein the manganese dioxide layer is also present in the inner pore structure of the nickel particle. The invention also relates to a method for producing such a manganese dioxide electrode, the use thereof in rechargeable alkaline-manganese batteries, and a rechargeable alkaline-manganese battery containing a manganese dioxide electrode according to the invention.

Abstract: The invention relates to a reversible manganese dioxide electrode, comprising an electrically conductive carrier material having a nickel surface, a nickel layer made of spherical nickel particles adhering to each other and having an inner pore structure applied to the carrier material, and a manganese dioxide layer applied to the nickel particles, wherein the manganese dioxide layer is also present in the inner pore structure of the nickel particle. The invention also relates to a method for producing such a manganese dioxide electrode, the use thereof in rechargeable alkaline-manganese batteries, and a rechargeable alkaline-manganese battery containing a manganese dioxide electrode according to the invention.

Abstract: Nickel electrodes having high mechanical stability and advantageous electrochemical properties, in particular, enhanced gas evolution in water electrolysis, are described. These electrodes comprising electrically conductive nickel wire mesh or a lattice-like nickel expanded metal webs, and a layer of mutually adherent nanoporous nickel particles applied only to either the nickel mesh wires or the nickel expanded metal webs, obtainable by partially reducing the spherical nickel hydroxide particles in a reducing atmosphere between 270 to 330° C. to obtain partially reduced, spherical Ni/NiO particles, producing a paste from the Ni/NiO particles, an organic and/or inorganic binder, a surfactant and, optionally, additional adjuvants, applying the paste as a coating to the electrically conductive nickel mesh or nickel expanded metal, and annealing the coated nickel mesh or nickel expanded metal in a reducing atmosphere at 500 to 800° C. A method for manufacturing the nickel electrode is also described.

Abstract: The invention relates to a reversible manganese dioxide electrode, comprising an electrically conductive carrier material having a nickel surface, a nickel layer made of spherical nickel particles adhering to each other and having an inner pore structure applied to the carrier material, and a manganese dioxide layer applied to the nickel particles, wherein the manganese dioxide layer is also present in the inner pore structure of the nickel particle. The invention also relates to a method for producing such a manganese dioxide electrode, the use thereof in rechargeable alkaline-manganese batteries, and a rechargeable alkaline-manganese battery containing a manganese dioxide electrode according to the invention.

Abstract: Nickel electrodes comprising an electrically conductive nickel sheet and a nickel layer deposited thereon which consists of spherical, porous nickel particles which adhere to each other, made by the method of partially reducing spherical nickel hydroxide particles in a reducing atmosphere at elevated temperatures to obtain partially reduced spherical Ni/NiO particles, preparing a paste from the Ni/NiO particles obtained and an organic and/or inorganic binder as well as further excipients as required, applying the paste in a layer to one or both sides of the electrically conductive nickel sheet, and tempering the coated nickel sheet in a reducing atmosphere at elevated temperatures. Self-supporting nickel layers of spherical, porous nickel particles which adhere to each other. Producing nickel electrodes and the self-supporting nickel layer, and use thereof, particularly as an electrode for water electrolysis.

Abstract: Nickel electrodes comprising an electrically conductive nickel sheet and a nickel layer deposited thereon which consists of spherical, porous nickel particles which adhere to each other, made by the method of partially reducing spherical nickel hydroxide particles in a reducing atmosphere at elevated temperatures to obtain partially reduced spherical Ni/NiO particles, preparing a paste from the Ni/NiO particles obtained and an organic and/or inorganic binder as well as further excipients as required, applying the paste in a layer to one or both sides of the electrically conductive nickel sheet, and tempering the coated nickel sheet in a reducing atmosphere at elevated temperatures. Self-supporting nickel layers of spherical, porous nickel particles which adhere to each other. Producing nickel electrodes and the self-supporting nickel layer, and use thereof, particularly as an electrode for water electrolysis.