A decoupled plating system is provided for producing lithium. In a general embodiment, the present disclosure provides a feed tank configured to supply a lithium-rich aqueous electrolyte stream, a plating tank that is configured to receive an organic electrolyte and plate out lithium metal from that organic electrolyte, and one or more lithium replenishment cells configured to receive both electrolytes, keep them separated, and selectively move lithium ions from the aqueous electrolyte into the spent organic electrolyte stream. The present system and process can advantageously reduce operating costs and/or improve energy efficiency in production of lithium metal and associated products.

Provided is a copper foil. The copper foil includes a copper layer and a protective layer disposed on the copper layer, wherein a surface of the protective layer has a maximum height roughness (R.sub.max) of 0.6 m to 3.5 m, a peak density (PD) of 5 to 110, and an oxygen atomic amount of 22 at % (atomic %) to 67 at %.

A chip component 10 comprises: an insulating substrate 1 on which a resistor 3 serving as a functional element is formed; a pair of internal electrodes (front electrodes 2, end surface electrodes 6, and back electrodes 5) that is formed to cover both end portions of the insulating substrate 1 and connected to the resistor 3; a barrier layer 8 that is formed on a surface of each of the internal electrodes and mainly composed of nickel; and an external connection layer 9 that is formed on a surface of the barrier layer 8 and mainly composed of tin, and the barrier layer 8 is composed of alloy plating (NiP) including nickel and phosphorus, which is formed by electrolytic plating, and a content rate of phosphorus in the alloy plating of an inner region is made different from that of an outer region so that at least the inner region of the barrier layer 8 has magnetic properties.

There is provided a method of manufacturing a metal sheet having an alloy plated layer, the method including a step of passing a metal strip continuously through a plating bath to perform electroplating in the plating bath, the plating bath including a plating liquid and an anode, the plating liquid containing two or more kinds of metal ions for forming the alloy plated layer, wherein an anode obtained by mixing two or more kinds of metal pellets is used as the anode, the metal pellets being formed of respective metals that form the alloy plated layer, wherein a mixing ratio of each metal pellet that constitutes the anode is determined based on a total surface area ratio of each metal pellet in the anode so that a dissolution ratio of each metal pellet that constitutes the anode is a dissolution ratio corresponding to a weight ratio of each metal that constitutes the alloy plated layer.

The present invention relates to processes that may be used singly or in combination to prevent lithium (or alkali metal) plating or dendrite buildup on bare substrate areas or edges of electrode rolls during alkaliation of a battery or electrochemical cell anode composed of a conductive substrate and coatings, in which the electrode rolls may be coated on one or both sides and may have exposed substrate on edges, or on continuous or discontinuous portions of either or both substrate surfaces.

In order to remove treatment liquid (21) from a planar material to be treated (10), which is transported in an assembly for the electrolytic or wet-chemical treatment of the material to be treated (10), or to promote the exchange of material on the surface of the material to be treated (10), a roll with a roll surface (4, 14) is provided. The roll surface (4, 14) is arranged relative to a transport path of the material to be treated (10) so that a gap (8, 18) remains between the roll surface (4, 14) and a useful region of the material to be treated (10) opposing the roll surface (4, 14), which extends over the useful region. The roll is driven rotatably so that at the gap (8, 18) a relative speed is produced between the roll surface (4, 14) and the material to be treated (10).

The present invention relates to processes that may be used singly or in combination to prevent lithium (or alkali metal) plating or dendrite buildup on bare substrate areas or edges of electrode rolls during alkaliation of a battery or electrochemical cell anode composed of a conductive substrate and coatings, in which the electrode rolls may be coated on one or both sides and may have exposed substrate on edges, or on continuous or discontinuous portions of either or both substrate surfaces.

A method for electrochemical deposition of refined lithium metal to form a lithium anode in situ in a lithium (Li) ion battery comprising providing a fully lithiated cathode, providing a metal anode, providing a block copolymer electrolyte membrane between the cathode and the metal anode, and polarizing the cathode and the metal anode in the lithium ion battery to cause Li ions to migrate from the cathode through the block copolymer electrolyte and cause the electrochemical deposition to deposit refined lithium metal on the metal anode to form the lithium anode.

Provided are an apparatus for continuous electrolytic treatment of a steel sheet that is suitable for producing a surface-treated steel sheet and a method for producing the surface-treated steel sheet using the apparatus for continuous electrolytic treatment of a steel sheet. The apparatus includes N pairs of tabular electrodes having a length L and being arranged to respectively face two surfaces of a steel sheet. Each electrode includes n sections arranged in the longitudinal direction of the electrode and disposed on the surface of the electrode facing the steel sheet surface. Each section is constituted by a conductive portion including an electrode portion having a length T1 and a nonconductive portion made by making an electrode portion having a length T2 nonconductive, where nN10, 0.96T2/(T1+T2)0.05, and 0.9T1/L0.1.

An auxiliary electrode for a lithium-ion battery includes a lithium source material. The auxiliary electrode is configured to selectively couple to a negative electrode of a lithium-ion battery to provide lithium for formation of a solid-electrolyte-inter-phase layer on a negative electrode.