A current collector for an anode-free all-solid-state battery is capable of effectively increasing a physical contact area between an electrolyte and a current collector and effectively reducing interfacial voids between the electrolyte and the current collector. In addition, an anode-free all-solid-state battery capable of stably increasing cycle life without overvoltage is provided.

A reactor for plasma-assisted chemical vapor deposition includes a plasma duct for containing one or more substrates to be coated by ions; an arc discharge generation system for generating a flow of electrons through the plasma duct from a proximal end toward a distal end of the plasma duct; a gas inlet coupled to the distal end for receiving a reactive gas; a gas outlet coupled to the proximal end for removing at least a portion of the reactive gas to generate a flow of the reactive gas through the plasma duct from the distal end toward the proximal end, to generate the ions from collisions between the electrons and the reactive gas; and a separating baffle positioned for restricting flow of the reactive gas out of the plasma duct to maintain a high pressure in the plasma duct to increase rate of deposition of the ions onto the substrates.

The invention concerns a method for surface treatment of a ceramic material in powder form, wherein said method comprising the step of providing a powder formed of a plurality of particles of the ceramic material to be treated, and wherein said ceramic powder particles are subjected to an ion implantation process by directing towards an external surface of said particles a beam of singly or multiply charged ions produced by a charge of singly or multiply charged ions, for example of the electron cyclotron resonance ECR type, wherein said particles have a generally polyhedral shape.

The invention also concerns a material in powder form, formed of a plurality of particles having a ceramic external layer and a ceramic core, wherein said particles have a generally polyhedral shape.

The present invention provides an apparatus and a method for coating small NdFeB magnets. The apparatus includes a furnace having a roller including at least one stirring piece disposed in the compartment. The stirring pieces have an isosceles triangle or trapezoidal shaped cross-section. The side wall of the furnace defines an inlet aperture and an outlet aperture disposed diametrically opposed to one another. A plurality of target source holders include two first target source holders and two second target source holders disposed on the side wall and spaced from one another and between the inlet aperture and the outlet aperture. The method includes a step of disposing a plurality of conductors with the small NdFeB magnets in the compartment of the roller. The small NdFeB magnets are mixed with the plurality of conductors in the roller with the roller being rotated of between 5 rpm and 20 rpm.

The description relates to a method, a coating device and a processing arrangement. According to different forms of embodiment, the method may comprise the following steps: producing a vacuum in a coating region and in a collection region; emitting solid particles with a first main direction of propagation through the coating region into the collection region; and evaporating a coating material with a second main direction of propagation into the coating region, the first main direction of propagation and the second main direction of propagation extending at an angle to each other such that the coating material is evaporated past the collection region.

ZnO sputtering is performed while a rolling body is housed in a basket made of a metal wire and is rotated. By setting a ratio of a mesh size of the basket to a diameter of the rolling body in a range of 40 to 95%, fine and uniform ZnO coating can be formed on a surface of the rolling body. By using the rolling body with ZnO coating prepared in this manner in a bearing which is rotated at high speed in a high-load state, a friction coefficient can significantly be lowered in comparison with a case of no coating.

Systems and methods electronic barcoding of particles. The methods comprise: performing operations by a spin coater to spin coat a single layer of particles onto a substrate; performing operations by a heat applicator to apply heat to the substrate so as to evaporate a liquid; and performing operations by at least one material depositor to transform the particles into Electronically Barcoded Particles (EBPs). EBPs are fabricated by: coating a portion of each said particle of the particles with a first conductive layer; depositing an insulative layer on the first conductive layer; and/or depositing a second conductive layer on the insulative layer so as to form a parallel plate capacitor on the particle. The parallel plate capacitor is tuned so that the particle has a capacitance that is different than the capacitances of other ones of the electronically barcoded particles.

The invention relates to a method for producing a battery cell (10), in particular a solid-state battery cell, wherein material particles (1) are provided with a first coating (3), wherein in a deposition step the material particles (1) having the first coating (3) are accelerated toward a substrate (112) in such a way that the first coating (3) of the material particles (1) joins with the first coating (3) of further material particles (1) upon hitting the substrate (112) such that a first layer (30) is formed, in particular without an input of heat from outside.

This product (10) for removing pollutants from a fluid includes, on the one hand, a porous body (12) having an outer and inner specific surface (14) and, on the other hand, a metallized layer (16), the thickness of which is at most nanoscale, covering at least part of the outer and inner specific surface (14) of the porous body (12). The metallized layer (16) includes at least a metal (Ag) bonded to the porous body (12) by chemical bonds (18) that result from the action of intramolecular forces. Further, the metallized layer (16) includes silicon (Si) also bonded to the porous body (12) by chemical bonds (18) resulting from the action of intramolecular forces.

The present disclosure provides an impregnation method that includes the steps of providing a workpiece to be impregnated, placing the workpiece in a bath of impregnating agent inside a vessel, and oscillating movement of a vibrating body inside the vessel during an impregnation period. The vibrating body creates oscillating pressure changes inside the bath by acting on the bath. the method further includes removing the workpiece from the bath after the impregnation period.