A method of recovering metals from electronic waste comprises providing a powder comprising electronic waste in at least a first reactor and a second reactor and providing an electrolyte comprising at least ferric ions in an electrochemical cell in fluid communication with the first reactor and the second reactor. The method further includes contacting the powders within the first reactor and the second reactor with the electrolyte to dissolve at least one base metal from each reactor into the electrolyte and reduce at least some of the ferric ions to ferrous ions. The ferrous ions are oxidized at an anode of the electrochemical cell to regenerate the ferric ions. The powder within the second reactor comprises a higher weight percent of the at least one base metal than the powder in the first reactor. Additional methods of recovering metals from electronic waste are also described, as well as an apparatus of recovering metals from electronic waste.

The invention relates to a method for manufacturing a plate material which is used in the electrochemical process of metal as a part of a cathode on which surface a metal is deposited. The surface roughness of the plate material for the adhesion between the metal deposit and the plate material is achieved with at least one treatment in a coil processing line.

The invention relates to a method for manufacturing a plate material which is used in the electrochemical process of metal as a part of a cathode on which surface a metal is deposited. The surface roughness of the plate material for the adhesion between the metal deposit and the plate material is achieved with at least one treatment in a coil processing line.

An electrochemical process comprises a step E.sup.l of electrolysis of an electrolyte in order to produce gaseous oxygen and a step of converting oxidation-reduction chemical energy into electrical energy with production of H.sub.2. The electrolyte comprises M.sup.m+ ions of a metal M corresponding to the redox pair (M.sup.m+/M), and A.sup.a+ ions of a depolarization additive A corresponding to a redox pair (A.sup.a+/A). Current is supplied between the anode and the cathode, A.sup.a+ and M.sup.m+ are deposited on the cathode respectively in the form of A and M during the electrolysis and gaseous oxygen is released at the anode. The supply of current between the anode and the cathode is then cut off. Depolarization occurs corresponding to the conversion step C°, with production of H.sub.2 and dissolution of M and A into M.sup.m+ and A.sup.a+ at the electrode acting as the cathode during step E.sup.l and the produced H.sub.2 is collected.

An electrochemical process comprises a step E.sup.l of electrolysis of an electrolyte in order to produce gaseous oxygen and a step of converting oxidation-reduction chemical energy into electrical energy with production of H.sub.2. The electrolyte comprises M.sup.m+ ions of a metal M corresponding to the redox pair (M.sup.m+/M), and A.sup.a+ ions of a depolarization additive A corresponding to a redox pair (A.sup.a+/A). Current is supplied between the anode and the cathode, A.sup.a+ and M.sup.m+ are deposited on the cathode respectively in the form of A and M during the electrolysis and gaseous oxygen is released at the anode. The supply of current between the anode and the cathode is then cut off. Depolarization occurs corresponding to the conversion step C°, with production of H.sub.2 and dissolution of M and A into M.sup.m+ and A.sup.a+ at the electrode acting as the cathode during step E.sup.l and the produced H.sub.2 is collected.

A method for extracting metal ions from water is provided that includes disposing two electrically conductive electrodes in water, where the water includes a target ion species in solution, where at least one of the electrically conductive electrodes is a functionalized electrode having species-specific adsorption of the target ion species, and providing electrical current to the electrically conductive electrodes such that the one or more target ion species are deposited to metallic form or metal oxides at the functionalized electrode by one or more electrochemical reactions.

A method for extracting metal ions from water is provided that includes disposing two electrically conductive electrodes in water, where the water includes a target ion species in solution, where at least one of the electrically conductive electrodes is a functionalized electrode having species-specific adsorption of the target ion species, and providing electrical current to the electrically conductive electrodes such that the one or more target ion species are deposited to metallic form or metal oxides at the functionalized electrode by one or more electrochemical reactions.

Provided are: an alloy powder that can be obtained from a waste lithium ion battery, wherein the alloy powder can be dissolved in an acid solution and enables recovery of metals contained in the alloy powder; and a method for producing the alloy powder. This alloy powder contains Cu and at least one of Ni and Co as constituent components, wherein a portion having a higher concentration of the at least one of Ni and Co than the average concentration in the entire alloy powder is distributed on at least the surface, and the phosphorus grade is less than 0.1% by mass. The method for producing the alloy powder includes a powdering step for powdering a molten alloy using a gas atomization method, the molten alloy containing Cu and at least one of Ni and Co as constituent components and having a phosphorus grade of less than 0.1% by mass.

A process for treating spent lithium ion batteries to recover metals is disclosed. The process includes discharging the spent lithium ion batteries. The discharged lithium ion batteries are shredded and roasted in a furnace to produce roasted material. The roasted material is sieved to separate a coarser fraction and a finer fraction. The coarser fraction comprises aluminium chips and copper chips. The finer fraction is further treated to recover copper, cobalt, and nickel sequentially with a purity of 99.3-99.9%. The process also recovers manganese as manganese dioxide and lithium as lithium carbonate. The process does not generate any solid waste as all the metals and by-products such as carbon powder and gypsum cake are saleable.

A process for treating spent lithium ion batteries to recover metals is disclosed. The process includes discharging the spent lithium ion batteries. The discharged lithium ion batteries are shredded and roasted in a furnace to produce roasted material. The roasted material is sieved to separate a coarser fraction and a finer fraction. The coarser fraction comprises aluminium chips and copper chips. The finer fraction is further treated to recover copper, cobalt, and nickel sequentially with a purity of 99.3-99.9%. The process also recovers manganese as manganese dioxide and lithium as lithium carbonate. The process does not generate any solid waste as all the metals and by-products such as carbon powder and gypsum cake are saleable.