A laminate including a metallic base material, a nickel-containing plating film layer formed on the metallic base material, and a gold plating film layer formed on the nickel-containing plating film layer, in which pinholes in the gold plating film layer are sealed with a passive film having a thickness of 15 nm or greater. Also disclosed is a constituent member of a semiconductor production device including the laminate and a method for producing the laminate.

A laminate including a metallic base material, a first nickel-containing plating film layer formed on the metallic base material, a gold plating film layer formed on the first nickel-containing plating film layer, a second nickel-containing plating film layer formed on the gold plating film layer, and a nickel fluoride film layer formed on the second nickel-containing plating film layer. Also disclosed is a method for producing the laminate as well as a constituent member of a semiconductor production device including the laminate.

A laminate including a metallic base material, a nickel-containing plating film layer formed on the metallic base material, and a gold plating film layer formed on the nickel-containing plating film layer, in which pinholes in the gold plating film layer are sealed with a fluorinated passive film having a thickness of 8 nm or greater. Also disclosed is a constituent member of a semiconductor production device including the laminate and a method for producing the laminate.

Provided are a magnetic disk and a method of fabricating the magnetic disk. The magnetic disk includes an aluminum alloy plate fabricated by a process involving a CC method and a compound removal process, and an electroless Ni—P plating layer disposed on the surface of the plate. The aluminum alloy plate is composed of an aluminum alloy containing 0.4 to 3.0 mass % (hereinafter abbreviated simply as “%”) of Fe, 0.1% to 3.0% of Mn, 0.005% to 1.000% of Cu, 0.005% to 1.000% of Zn, with a balance of Al and unavoidable impurities. In the magnetic disk, the maximum amplitude of waviness in a wavelength range of 0.4 to 5.0 mm is 5 nm or less, and the maximum amplitude of waviness in a wavelength range of 0.08 to 0.45 mm is 1.5 nm or less.

An autocatalytic gold bath capable of depositing gold from solution onto a substrate, wherein the substrate has one or more metal layers thereon. The autocatalytic gold bath includes (a) a chelator; (b) a gold salt; and (c) a reducing agent, wherein the reducing agent comprises an organic molecule having more than one carbon atom on the organic molecule. A process of plating gold onto the surface of the one or more metal layers on the substrate is also included. The gold plating bath can be used to deposit a final finish to the surface of the one or more metal layers which can be formed in an ENIG, ENEPIG, EPAG, direct gold over copper or gold over silver process.

An apparatus is provided. The apparatus may include one or more of a container, a first magnet assembly, and a second magnet assembly. The container includes an open top and is configured to hold a liquid chemical solution. The first magnet assembly includes a first magnet having a first polarity and a cover, coupled to the first magnet. The cover is configured to be movable between an open and a closed position and limit evaporation of the solution when the cover is in the closed position. The second magnet assembly includes a second magnet having a second polarity. In response to a command, the second magnet assembly is configured to move the cover to the open position without direct contact to the first magnet assembly in response to a command.

An aluminum alloy cage and a method for producing the same. The aluminum alloy cage has a shot-peened aluminum alloy cage substrate and a coating formed on the surface of shot-peened aluminum alloy cage substrate, the coating including at least one nickel containing layer. The aluminum alloy cage has high fatigue strength, excellent corrosion resistance, high surface hardness and low surface friction coefficient, and exhibits excellent surface lubricity and wear resistance.

An aluminum alloy cage and a method for producing the same. The aluminum alloy cage has a shot-peened aluminum alloy cage substrate and a coating formed on the surface of shot-peened aluminum alloy cage substrate, the coating including at least one nickel containing layer. The aluminum alloy cage has high fatigue strength, excellent corrosion resistance, high surface hardness and low surface friction coefficient, and exhibits excellent surface lubricity and wear resistance.

Provided is a device and a method for forming a metal plating film having a thick film thickness by a solid substitution-type electroless plating method. The present disclosure relates to a film formation device for forming a film of a first metal on a plating film of a second metal by a solid substitution-type electroless plating method, comprising: a conductive mounting base; a third metal; an insulating material; a microporous membrane; a plating bath chamber; and a pressing unit, wherein the third metal has an ionization tendency larger than ionization tendencies of the first metal and the second metal, and wherein the insulating material is installed between a base material and the third metal so as to contact respective materials of the base material and the third metal when the base material having the plating film of the second metal is installed.

A method to produce a flexible substrate is described. A base film material of cyclo-olefin polymer (COP) is provided. A surface of the COP base film is irradiated with UV light to form a functional group on the COP surface. Thereafter, the surface is treated with an alkaline degreaser. Thereafter, a Ni—P seed layer is electrolessly plated on the surface. A photoresist pattern is formed on the Ni—P seed layer. Copper traces are plated within the photoresist pattern. The photoresist pattern is removed and the Ni—P seed layer not covered by the copper traces is etched away to complete the flexible substrate. Alternatively, a biocompatible flexible substrate is formed using a Ni—P seed layer with a biocompatible surface finishing instead of copper.