Abstract: The present disclosure concerns a solid state electrolyte for providing an ion conductive connection between a negative and positive electrode in a battery, the solid state electrolyte comprising: an ion conductive matrix comprising a polymer, and a metal salt dispersed in the ion conductive matrix, and a first ceramic material, wherein at least one of the faces of the ion conductive matrix for connecting to the negative or positive electrode, is infiltrated with the first ceramic material to form a first, hybrid interface layer.

Abstract: The present disclosure concerns a rechargeable battery cell comprising a compressible elastic composite material to form one or more of: a compressible and elastic first current collector; and a compressible and elastic positive electrode; and a compressible and elastic solid state electrolyte; and a compressible and elastic negative electrode; and a compressible and elastic second current collector, wherein the compressible elastic composite material comprises a plurality of compressible pores.

Abstract: A substrate comprises carbon nanotubes, oriented largely parallel in a direction away from the substrate. In a plane along a surface of said substrate carbon nanotubes are formed in first cells of a connected structure of carbon nanotubes. Said first cells formed within a second structure of second cells, the carbon nanotubes are thereby patterned in a structure of first cells, nested in a structure of second cells. The first cells comprise at least one opening, without carbon nano tubes, to provide access to the surface of the substrate. Second cells are separated from each other by a trench to prevent carbon nanotubes of a second cell from contacting carbon nanotubes of another second cell across a first gap formed by said trench. The trench provides access to the substrate.

Abstract: A method of manufacturing a Lithium battery with a substrate current collector formed of pillars on a substrate face, wherein the method comprises: forming elongate and aligned structures forming electrically conductive pillars on the substrate face with upstanding pillar walls; wherein the pillars are formed with a first electrode, a solid state electrolyte layer provided on the first electrode; and a second electrode layer, wherein the pillars are dimensioned in such a way that adjacent pillars are merged and a topstrate current collector is formed of complementary interspace structures between the merged pillars.

Abstract: A method of manufacturing a battery with a substrate current collector, wherein the method comprises: forming elongate and aligned electrically conductive structures on the substrate face with upstanding walls; wherein the walls are formed with a first electrode layer covering said walls, and a solid state electrolyte layer provided on the first electrode layer; and wherein a second electrode layer is formed by covering the electrolyte layer with an electrode layer; and forming a top current collector layer in electrical contact with the second electrode layer, wherein the second electrode layer is shielded from the conductive structure by an insulator covering a part of said conductive structure adjacent an end side thereof.

Abstract: A method of manufacturing a battery with a substrate current collector, wherein the method comprises: forming elongate and aligned electrically conductive structures on the substrate face with upstanding walls; wherein the walls are formed with a first electrode layer covering said walls, and a solid state electrolyte layer provided on the first electrode layer; and wherein a second electrode layer is formed by covering the electrolyte layer with an electrode layer; and forming a top current collector layer in electrical contact with the second electrode layer, wherein the second electrode layer is shielded from the conductive structure by an insulator covering a part of said conductive structure adjacent an end side thereof.

Abstract: A method of manufacturing a Lithium battery with a substrate current collector formed of pillars on a substrate face, wherein the method comprises: forming elongate and aligned structures forming electrically conductive pillars on the substrate face with upstanding pillar walls; wherein the pillars are formed with a first electrode, a solid state electrolyte layer provided on the first electrode; and a second electrode layer, wherein the pillars are dimensioned in such a way that adjacent pillars are merged and a topstrate current collector is formed of complementary interspace structures between the merged pillars.