Provided is a molded circuit component 300 in which a metal layer 200 is formed with high adhesion by giving a degree of freedom to a base material 100. In the molded circuit component 300 in which the metal layer 200 is formed in a processing region 110 in the base material 100, a plurality of recesses 120 each having a plurality of holes 130 are continuously formed in the processing region 110, the processing region 110 has a ratio of a width to a maximum depth with respect to a surface of the base material 100 of 10:1 to 6:1, the processing region 110 is formed to have a width in a range of 20 μm to 200 μm, and formed to have a maximum depth with respect to the surface of the base material 100 in a range of 2 μm to 30 μm, the metal layer 200 can be formed in the processing region 110 by laminating using a plating method, and a catalyst that reacts with a metal that forms the metal layer 200 at the time of the lamination is attached to the holes 130 and the recesses 120.

A wiring board includes a substrate having main surfaces and an electrode containing Cu or Ag as a main component on at least one main surface of the substrate, wherein the electrode protrudes from the substrate, a surface of the electrode is covered by a first Ni film containing crystalline Ni as a main component, a surface of the first Ni film is covered by a second Ni film containing amorphous Ni as a main component, and the first Ni film covers a part of a first corner where a side surface of the electrode is in contact with the substrate.

An electroless nickel plating solution and a method of using the same to produce a nickel deposit having a phosphorus content that remains at about 12% throughout the lifetime of the electroless nickel plating solution is disclosed. The electroless nickel plating solution comprises (a) a source of nickel ions; (b) a reducing agent comprising a hypophosphite; and (c) a chelation system comprising: (i) one or more dicarboxylic acids; and (ii) one or more alpha hydroxy carboxylic acids. The electroless nickel plating solution may also comprise stabilizers and brighteners.

An electroless nickel plating solution and a method of using the same to produce a nickel deposit having a phosphorus content that remains at about 12% throughout the lifetime of the electroless nickel plating solution is disclosed. The electroless nickel plating solution comprises (a) a source of nickel ions; (b) a reducing agent comprising a hypophosphite; and (c) a chelation system comprising: (i) one or more dicarboxylic acids; and (ii) one or more alpha hydroxy carboxylic acids. The electroless nickel plating solution may also comprise stabilizers and brighteners.

The present invention relates to the use of water soluble lanthanide compounds as stabilizer in electrolytes for electroless metal deposition, an electrolyte as well as a method for the electroless deposition of metals, particularly layers of nickel, copper, cobalt, boron, silver, palladium or gold, as well as layers of alloys comprising at least one of the aforementioned metals as alloying metal.

An electrode, process for preparing the electrode and devices thereof. An electrode comprising at least one metal deposited on a substrate; and at least one electrically conducting polymer. The devices comprising the electrode for energy storage and molecular separation.

The present invention relates to aqueous plating bath compositions and methods for deposition of nickel and nickel alloys utilizing mixtures of stabilizing agents comprising ions of group IIIA metals and iodine containing, inorganic compounds in order to enhance bath stability.

The present invention relates to aqueous plating bath compositions and methods for deposition of nickel and nickel alloys utilizing mixtures of stabilizing agents comprising ions of group IIIA metals and iodine containing, inorganic compounds in order to enhance bath stability.

Method for producing an object by additively manufacturing a preform of the object from a building material comprising a polymer. The preform is encapsulated with a metal or metal alloy encapsulant that is capable of withstanding temperatures greater than the preform. The encapsulated preform is heated at a predetermined temperature and for a period of time, such that the preform at least partially transmutes into the form of a carbonaceous solid.

Disclosed are an anode active material for lithium secondary batteries, the anode active material comprising: a core part including a carbon-silicon complex and having a cavity therein; and a coated layer which is formed on the surface of the core part and includes a phosphor-based alloy.