Disclosed are electrochemical devices, such as lithium ion battery electrodes, lithium ion conducting solid-state electrolytes, and solid-state lithium ion batteries including these electrodes and solid-state electrolytes. Also disclosed are methods for making such electrochemical devices. Also disclosed are composite electrodes for solid state electrochemical devices. The composite electrodes include one or more separate phases within the electrode that provide electronic and ionic conduction pathways in the electrode active material phase.

A three-dimensional metallic foam is fabricated with an active oxide material for use as an anode for lithium batteries. The porous metal foam, which can be fabricated by a freeze-casting process, is used as the anode current collector of the lithium battery. The porous metal foam can be heat-treated to form an active oxide material to form on the surface of the metal foam. The oxide material acts as the three-dimensional active material that reacts with lithium ions during charging and discharging.

Disclose are a cathode of an all-solid lithium battery, and a secondary battery system using the same. The cathode includes a lithium composite, and a method of manufacturing the lithium composite comprises: dispersing a solid electrolyte to be uniformly distributed in the pores of a mesoporous conductor to provide a solid electrolyte composite, and coating the solid electrolyte composite on the surface of a lithium compound including nonmetallic solids such as S, Se, and Te.

A method of manufacturing a battery electrode includes casting a solid battery electrode from a slurry including electrode particles, a binder, and a solvent, wherein residual solvent remains after the casting and the binder remains at least partially elastic. The solid battery electrode then undergoes flash-freezing such that the residual solvent forms dendritic ice having a pattern, and then the dendritic ice is removed from the solid battery electrode, thereby rearranging the electrode particles and the binder into a microstructure that represents a geometric negative of the pattern of the dendritic ice.

A lithium metal is physically pressed to a silicon wafer having a uniform intaglio or embossed pattern formed thereon in advance, or liquid lithium is applied to the silicon wafer and may then be cooled in order to form a uniform pattern on the surface of the lithium metal.

Methods for making lead-carbon coupling, lead-carbon electrode sheets, and a lead-carbon battery are revealed. The coupling methods consist of steps of assembling the carbon material that contains oxygen functional groups or metal precursors and lead material in contact with each other and then heating the assembled lead-carbon pair to form lead oxides or metal carbides as a bridge to form coupled lead-carbon interface with high electrochemical and mechanical stability. This coupled lead-carbon structure is applied to form lead-carbon electrode sheets and is further used as electrode sheets of lead-carbon batteries by lead welding.

A three-dimensional metallic foam is fabricated with an active oxide material for use as an anode for lithium batteries. The porous metal foam, which can be fabricated by a freeze-casting process, is used as the anode current collector of the lithium battery. The porous metal foam can be heat-treated to form an active oxide material to form on the surface of the metal foam. The oxide material acts as the three-dimensional active material that reacts with lithium ions during charging and discharging.

Pyrolysis (carbonization) of various plastics, including recycled plastic, can generate carbonaceous materials cheaply and in bulk, which can then be converted into energy storage device materials, e.g., carbon anode active material for Li-ion batteries. The plastic can be dissolved in a suitable solvent or acid, or can be melted. Once liquefied it can be loaded into vessels for extrusion via an electrospinner. Polymer fibers may be formed from the liquefied plastic on the nano- and micro scales, and collected on a substrate, forming a fabric. These fibers can be converted to high purity carbon and used as electrode materials in batteries and supercapacitors. The fibers can also be coated with Ppy prior to pyrolysis; this helps fibers retain their morphology during carbonization. The fibers can also be loaded with additive particles to enhance their electrochemical performance or alter the composite properties.

An anode for an aluminum-air battery may include an anode body, which may contain particles of an aluminum alloy in a sodium matrix. An electrolyte for an aluminum-air battery may consist of one of an aqueous acid and an aqueous lye containing at least one halogen and at least one surfactant.

Disclose are a cathode of an all-solid lithium battery, and a secondary battery system using the same. The cathode includes a lithium composite, and a method of manufacturing the lithium composite comprises: dispersing a solid electrolyte to be uniformly distributed in the pores of a mesoporous conductor to provide a solid electrolyte composite, and coating the solid electrolyte composite on the surface of a lithium compound including nonmetallic solids such as S, Se, and Te.