A component for a vehicle comprises two or more first members each formed of a plateable resin and defining a front surface, wherein the front surfaces of the first members (i) are spaced apart from each other such that they appear discontinuous and (ii) collectively correspond to an outer surface of the component, a second member formed of a non-plateable resin and connected to each of the first members and a chrome plating applied to one or more exposed surfaces of each of the first members. A method of manufacturing the component involves utilizing one or more molds and removing a non-plated component comprising the first members and the second member from one of the one or more molds, attaching the non-plated component to a plating rack, such as via a permanent or temporary conductive circuit, and then performing the chrome plating.

A component for a vehicle comprises two or more first members each formed of a plateable resin and defining a front surface, wherein the front surfaces of the first members (i) are spaced apart from each other such that they appear discontinuous and (ii) collectively correspond to an outer surface of the component, a second member formed of a non-plateable resin and connected to each of the first members and a chrome plating applied to one or more exposed surfaces of each of the first members. A method of manufacturing the component involves utilizing one or more molds and removing a non-plated component comprising the first members and the second member from one of the one or more molds, attaching the non-plated component to a plating rack, such as via a permanent or temporary conductive circuit, and then performing the chrome plating.

A method of producing a die for forming an interior component of a vehicle includes: setting a temperature of a plating bath in a range from 25 to 40° C.; immersing at least a forming surface on a base for the die in the plating bath; and feeding a current to the base with a current density in a range from 20 to 80 A/dm.sup.2 until a metal layer is formed on the forming surface.

A lead member includes: a lead conductor having a first main surface and a second main surface that is an opposite side of the first main surface; and a resin portion, while exposing both end portions of the lead conductor in a first direction, covering the first main surface, the second main surface, and both side surfaces between the both end portions of the lead conductor, wherein the lead conductor includes a metal substrate, and a colored layer formed on at least a portion of a surface of the metal substrate, wherein in an entire wavelength band of 220 nm or more and 850 nm or less, when a total reflectance of barium sulfate is defined as 1.0, a regular reflectance of the colored layer is 0.3 or less.

Provided are an electrodeposited copper foil, an electrode comprising the same, and a lithium-ion secondary battery comprising the same. The electrodeposited copper foil has a drum side and a deposited side opposing the drum side, wherein at least one of the drum side and the deposited side exhibits a void volume value (Vv) in the range of 0.17 μm.sup.3/μm.sup.2 to 1.17 μm.sup.3/μm.sup.2; and an absolute value of a difference between a maximum height (Sz) of the drum side and a Sz of the deposited side is in the range of less than 0.60 μm.

An anti-coking nanomaterial based on a stainless steel surface. In percentage by weight, the nanomaterial comprises: 0 to 3% of carbon, 23% to 38% of oxygen, 38% to 53% of chromium, 10% to 35% of ferrum, 0 to 2% of molybdenum, 0 to 4% of nickel, 3.5 to 5% of silicon, 0 to 1% of calcium, and the balance of impurity elements. Also disclosed are a preparation method for the anti-coking nanomaterial, the anti-coking nanomaterial that is based on a stainless steel surface and that is prepared by using the preparation method, and a stainless steel substrate comprising the anti-coking nanocrystalline material.

An anti-coking nanomaterial based on a stainless steel surface. In percentage by weight, the nanomaterial comprises: 0 to 3% of carbon, 23% to 38% of oxygen, 38% to 53% of chromium, 10% to 35% of ferrum, 0 to 2% of molybdenum, 0 to 4% of nickel, 3.5 to 5% of silicon, 0 to 1% of calcium, and the balance of impurity elements. Also disclosed are a preparation method for the anti-coking nanomaterial, the anti-coking nanomaterial that is based on a stainless steel surface and that is prepared by using the preparation method, and a stainless steel substrate comprising the anti-coking nanocrystalline material.

[Problem] An object is to provide novel composite copper foils. [Means to solve the problem] A composite copper foil comprises a copper foil and a layer of metal other than copper, the metal layer being formed on at least a part of a surface of the copper foil, wherein at least a part of the composite copper foil has protrusions on a surface thereof, and each protrusion has a height of 10 nm or more but 1000 nm or less in a cross-section of the composite copper foil.

A method for creating a chrome-plated surface having a matte finish that typically includes: controlling a resistance of a current bridge circuit; depositing a first chromium layer on a substrate positioned in a chromium bath, wherein the first chromium layer is deposited by supplying current from a power source that is electrically connected to the substrate and to anodes positioned in the chromium bath; etching the first chromium layer by engaging a current bridge that closes the current bridge circuit; depositing a first intermediate chromium layer, wherein the first intermediate chromium layer is deposited by supplying current from the power source; etching the first intermediate chromium layer, wherein the first intermediate chromium layer is etched by engaging the current bridge; and depositing a final chromium layer, wherein the final chromium layer is deposited by supplying current from the power source.

A method for creating a chrome-plated surface having a matte finish that typically includes: controlling a resistance of a current bridge circuit; depositing a first chromium layer on a substrate positioned in a chromium bath, wherein the first chromium layer is deposited by supplying current from a power source that is electrically connected to the substrate and to anodes positioned in the chromium bath; etching the first chromium layer by engaging a current bridge that closes the current bridge circuit; depositing a first intermediate chromium layer, wherein the first intermediate chromium layer is deposited by supplying current from the power source; etching the first intermediate chromium layer, wherein the first intermediate chromium layer is etched by engaging the current bridge; and depositing a final chromium layer, wherein the final chromium layer is deposited by supplying current from the power source.