Methods for fabricating dendritic structures and tags include introducing an electrolyte material onto a substrate, into a substrate, or both onto and into a substrate, and applying an electrical potential to at least one pair of electrodes positioned on the substrate to form one or more dendritic structures on the substrate.

Methods for fabricating dendritic structures and tags include introducing an electrolyte material onto a substrate, into a substrate, or both onto and into a substrate, and applying an electrical potential to at least one pair of electrodes positioned on the substrate to form one or more dendritic structures on the substrate.

A manufacturing method of a home appliance including a hairline according to disclosed embodiment includes forming at least one plating layer on the base material, processing the transverse hairline on the upper surface of the plating layer by tilting the hairline processing wheel at a predetermined angle, and forming a coating layer on the hairline.

A manufacturing method of a home appliance including a hairline according to disclosed embodiment includes forming at least one plating layer on the base material, processing the transverse hairline on the upper surface of the plating layer by tilting the hairline processing wheel at a predetermined angle, and forming a coating layer on the hairline.

An electrode wire includes a brass core, a Cu—Zn alloy layer coated on the brass core, and a surface layer. The surface layer includes CuO, ZnO, Cu.sub.2(OH).sub.2CO.sub.3, and a Cu—Zn intermetallic compound. The surface layer is in the shape of particles or sheets spaced apart on the Cu—Zn alloy layer; and the Cu—Zn alloy layer is exposed with respect to spaces between the particles or sheets.

Processes for producing layered components that may include depositing a strike layer on a substrate; forming a nanomaterial layer on the strike layer, the nanomaterial layer having a nanotextured surface comprising a plurality of nanofeatures; embedding a polymeric material at least partially within the nanotextured surface; and separating the strike layer from the substrate to obtain the layered component. Layered components that may include a nanomaterial layer having a nanotextured surface comprising a plurality of nanofeatures; and a polymeric material at least partially embedded within the nanotextured surface. Nanotextured polymeric materials and layered components produced by various processes.

Provided is a method that allows for firm joining of power module components even if a joining area is large. The method includes: forming an oxygen ion conductor layer on a surface of one of a first member to be joined containing metal and a second member to be joined containing ceramic; arranging the first member to be joined and the second member to be joined so that they are in contact with each other via the oxygen ion conductor layer; connecting the first member to be joined to one of a positive electrode side and a negative electrode side of a voltage application device and the second member to be joined to the other; and applying a voltage between the first member to be joined and the second member to be joined to join the first member to be joined and the second member to be joined together.

Provided is a film forming apparatus and a film forming method for forming a metal film capable of reducing the occurrence of discoloring or alteration of the metal film caused by drying of an electrolytic solution remaining on the surface of the formed metal film. A space where the metal film exists is sealed between a housing and a mount base in a state where the solid electrolyte membrane is in contact with the metal film. The film forming apparatus includes a water supply unit supplying a wash water to the sealed space such that the wash water flows onto the surface of the metal film being in contact with the solid electrolyte membrane, and a water discharge unit discharging a wash water from the sealed space such that the wash water having flown onto the surface of the metal film flows out from the surface of the metal film.

Provided is a film forming apparatus and a film forming method for forming a metal film capable of reducing the occurrence of discoloring or alteration of the metal film caused by drying of an electrolytic solution remaining on the surface of the formed metal film. A space where the metal film exists is sealed between a housing and a mount base in a state where the solid electrolyte membrane is in contact with the metal film. The film forming apparatus includes a water supply unit supplying a wash water to the sealed space such that the wash water flows onto the surface of the metal film being in contact with the solid electrolyte membrane, and a water discharge unit discharging a wash water from the sealed space such that the wash water having flown onto the surface of the metal film flows out from the surface of the metal film.

The present invention relates to an electrode comprising an electrically conductive substrate of which at least one portion of the surface is covered with a metal deposit of copper, the surface of said deposit being in an oxidised, sulphurised, selenised and/or tellurised form and the deposit having a specific surface area of more than 1 m.sup.2/g; a method for preparing such an electrode; and a method for oxygenising water with dioxygen involving such an electrode.