In an anode for a secondary battery, a method for preparing the anode, a secondary battery including the anode, and an apparatus for applying a magnetic field, the anode for a secondary battery includes an anode mixture layer on at least one surface of an anode current collector, in which a z-tensor value of a pore in the anode mixture layer is 0.25 or more. The method includes applying an anode mixture slurry including an anode active material to at least one surface of an anode current collector; and drying the anode mixture slurry to form an anode mixture layer. During at least one of the applying and the drying, a magnetic field in which a direction of a line of magnetic force and magnetic force strength change is applied from both upper and lower surfaces of the anode current collector to orient the anode active material and the pore.

Disclosed is a transparent anode thin film comprising a transparent anode active material layer, wherein the transparent anode active material layer comprises a Si-based anode active material having a composition represented by the following [Chemical Formula 1]:
SiN.sub.x  [Chemical Formula 1] (wherein 0<x≤1.5).

The present disclosure relates to a slurry composition for a positive electrode for a lithium secondary battery, and a positive electrode and a lithium secondary battery including the same, and more particularly, when manufacturing the positive electrode for the lithium secondary battery including slurry coating process, it is possible to increase the processability during the manufacture of the positive electrode for the lithium secondary battery, by manufacturing the positive electrode using a slurry composition for positive electrode with thixotropy that can secure flowability to an extent that can respond flexibly to changes in the coating speed of the slurry.

Articles and methods including composite layers for protection of electrodes in electrochemical cells are provided. In some embodiments, the composite layers comprise a polymeric material and a plurality of particles.

Embodiments of the present application provide a lithium metal negative electrode, a preparation method therefor and related lithium metal battery and device. The lithium metal negative electrode may comprise: a negative electrode current collector; at least one lithium-based metal layer provided on at least one surface of the negative electrode current collector; and an ion-conducting polymer modification layer, which is located on the surface of one of the at least one lithium-based metal layer and comprises at least catalytic amount of a Lewis acid, the Lewis acid containing cations of a metal capable of forming an alloy-type active material with lithium.

Disclosed is a method for manufacturing a lithium metal secondary battery including a lithium metal electrode as a negative electrode, wherein the lithium metal electrode has a protective layer formed thereon, and the lithium metal secondary battery is discharged before its initial charge during an activation step of the lithium metal secondary battery so that stripping occurs on the surface of the lithium metal electrode.

An active material and a surface treatment method of the active material are provided. A surface of the active material may be treated with a coating layer including a first metal oxide containing lithium, and a second metal oxide.

A composite for use as an electrode, the composition comprising a uniformly distributed spontaneously formed segregated network of carbon nanotubes, metallic nanowires or a combination thereof, and a particulate active material, and in which the composite is free of carbon black and has no additional polymeric binder.

A liquid composition includes particles and a solvent, wherein a contact angle of the liquid composition with respect to a substrate is greater than a contact angle of the solvent with respect to the substrate, and the contact angle of the substrate with respect to water observed 9 seconds after the substrate comes into contact with the water is 45 degrees to 75 degrees.

Provided are printed electrochemical cells, which utilize zinc salts for ionic transfer, and methods of fabricating such cells. In some examples, a printed electrochemical cell comprises a positive electrode with a positive current collector having a two-dimensional shape and comprising an electrolyte-facing surface formed by the graphite. For example, the positive current collector may be a graphite foil or an aluminum foil with a graphite coating. The cell also comprises electrolyte comprising an electrolyte salt and an electrolyte solvent. For example, the electrolyte salt comprises a zinc salt with a concentration of at least 30% by weight in the electrolyte. The cell is fabricated by printing a positive active material layer over the positive current collector, printing one or more electrolyte layers on various cell components, and laminating a separator layer between the positive and negative electrodes while soaking the separator layer with the electrolyte.