An electrode, a lithium battery including the same, and a method of preparing the electrode are provided. The electrode includes an electrode active material layer including an electrode active material and a binder; and an electrode current collector at a portion of the electrode active material layer and at one side of the electrode active material layer, or at a portion of the electrode active material layer between opposing sides of the electrode active material layer, wherein the electrode active material layer includes a plurality of through-holes.

Embodiments described herein relate generally to electrochemical cells having semi-solid electrodes that are coated on only one side of a current collector. In some embodiments, an electrochemical cell includes a semi-solid positive electrode coated on only one side of a positive current collector and a semi-solid negative electrode coated on only one side of a negative current collector. A separator is disposed between the semi-solid positive electrode and the semi-solid negative electrode. At least one of the semi-solid positive electrode and the semi-solid negative electrode can have a thickness of at least about 250 μm.

A slurry is prepared by mixing a solid electrolyte material, an electrode active material, and a dispersion medium. The eluted amount of a halogen element in the dispersion medium in the slurry is measured. When the eluted amount is within a reference range, the slurry is rated as a good slurry. An electrode is produced by applying the good slurry to a surface of a base material and drying.

Provided is a slot die coater including: at least two die blocks; a shim plate provided between the two die blocks to form a slot; and a manifold provided in the die block and configured to accommodate a coating solution, wherein the slot die coater is configured to discharge and apply the coating solution to a substrate. The shim plate includes an open portion such that a coating width of a coating layer applied on the substrate is determined, and a part of a corner of the shim plate defining the open portion from which the coating solution is discharged, is chamfered. When a thickness of the coating solution applied on the substrate is A, the chamfered part has a shape cut by a depth equal to or greater than A to inside of the corner in a region away inward by A from the end of the shim plate.

A method for manufacturing a lithium ion battery with a capacitance greater than 1 mA h, including the deposition of at least one dense layer, which can be an anode and/or a cathode and/or an electrolyte, by a method of depositing a dense layer. The method includes: supplying a substrate and a suspension of non-agglomerated nanoparticles of a material P; depositing a layer on the substrate using the suspension; drying the layer thus obtained; densifying the dried layer by mechanical compression and/or heat treatment. The method of depositing being characterised in that the suspension of non-agglomerated nanoparticles of material P includes nanoparticles of material P having a size distribution, said size being characterised by the value of D50 thereof, such that: the distribution includes nanoparticles of material P of a first size D1 between 20 nm and 50 nm, and nanoparticles of material P of a second size D2 characterised by a value D50 at least five times less than that of D1, or the distribution has a mean size of nanoparticles of material P less than 50 nm, and a standard deviation to mean size ratio greater than 0.6.

The present technology relates to a method of managing a sliding region of an electrode, and the method includes: determining a specific region where a positive electrode and a negative electrode, which are subjects of management to be used in manufacturing an electrode assembly, face each other and setting a measurement location in the specific region; measuring a thickness and a loading amount of each electrode mixture layer of the positive electrode and the negative electrode at the set measurement location; measuring a thickness and a loading amount of an electrode mixture layer at each central portion of the positive electrode and the negative electrode; and calculating a ratio of the thickness of the electrode mixture layer of the positive electrode and the negative electrode to the thickness of the central portion.

A battery including a composite electrode protection layer and a method for manufacturing the same are provided. The battery includes a negative electrode that includes a current collector containing a conductive material, an anode active material positioned on a surface of the current collector and containing metallic lithium, and a protection layer covering an exposed surface of the anode active material and the protection layer may include a polymer-ceramic composite material containing an ultraviolet cured resin or electron-beam cured resin and a ceramic.

A web coating platform for depositing molten metal on flexible substrates is provided. The web coating platform can be used for manufacturing solid lithium anodes for use in energy storage devices, for example, rechargeable batteries. The coating platform can be designed for double-sided coating of a continuous flexible substrate (e.g., a copper foil) with molten lithium followed by double-sided lamination or passivation. The coating platform integrates novel coating elements unique to handling and processing molten metals. For example, some implementations of the present disclosure incorporate double-sided molten metal coating elements, which include at least one of a molten metal application assembly (e.g., kiss roller, slot-die, Meyer bar, and/or gravure roller), a primary melt pool assembly, a secondary melt pool assembly, and an engagement mechanism.

A method of manufacturing a shim for a die coater is disclosed herein. In some embodiments, a method of manufacturing a shim for a die coater, where the shim is applied to an electrode slurry die of the die coater and used for discharging an electrode slurry from the die coater, comprising milling a surface of a metal plate to prepare the shim. Using the method herein, it is possible to manufacture a shim for a die coater having a low thickness deviation by processing the shim for a die coater through a milling process.

A laminate for a secondary battery includes an electrode and a separator that are stacked via an adhesive material. For this laminate, when a value measured for shear peel strength between the electrode and the separator with varying temperature is taken to be A (mN/mm.sup.2), a value of maximum heat shrinkage force for the separator determined by thermomechanical analysis is taken to be B (mN/mm.sup.2), and a temperature at which heat shrinkage force for the separator determined by thermomechanical analysis decreases to a value (mN/mm.sup.2) that is 20% higher than a value (mN/mm.sup.2) of heat shrinkage force at 30° C. is taken to be a heat shrinkage end temperature α (°C.), A has a value satisfying A > B in a temperature range of not lower than 25° C. and not higher than the heat shrinkage end temperature α°C.