An apparatus for electroplating includes a cup configured to support a substrate, and a cone including at least three distance measuring devices arranged on a lower surface thereof and facing the substrate. Each distance measuring device is configured to transmit a laser pulse towards the substrate, the laser pulse impinging the substrate, receive a reflected laser pulse from the substrate, calculate a turnaround time of the laser pulse, and calculate a distance between the distance measuring device and the substrate using the turnaround time for determining an inclination of the substrate.

Devices including a substrate and a plurality of coil portions disposed on the substrate. The plurality of coil portions electrically coupled to form a coil structure.

An oxide superconducting wire includes a superconducting laminate including an oxide superconducting layer disposed, either directly or indirectly, on a substrate, and a stabilization layer which is a Cu plating layer covering an outer periphery of the superconducting laminate. An average crystal grain size of the Cu plating layer is 3.30 μm or more and equal to or less than a thickness of the Cu plating layer.

A method for plating a work piece includes forming a work piece, where the work piece includes first and second segments that are electrically isolated. The first segment is connected in a first circuit and the second segment is connected in a second circuit. The first circuit may include a first power source and the second circuit may include a second power source. The work piece and the first and second segments may be disposed in a common solution, and current may be applied in the first circuit and the second circuit to create first and second metal surfaces. The first and second metal surfaces may be made from the same base metal. The first and second metal surfaces may be created simultaneously, with the work piece and the first and second segments disposed in a common solution.

A method for plating a work piece includes forming a work piece, where the work piece includes first and second segments that are electrically isolated. The first segment is connected in a first circuit and the second segment is connected in a second circuit. The first circuit may include a first power source and the second circuit may include a second power source. The work piece and the first and second segments may be disposed in a common solution, and current may be applied in the first circuit and the second circuit to create first and second metal surfaces. The first and second metal surfaces may be made from the same base metal. The first and second metal surfaces may be created simultaneously, with the work piece and the first and second segments disposed in a common solution.

One object of the present disclosure is to improve the accuracy of detection of an abnormality of various devices, and/or to advance the timing of detection of an abnormality. There is provided an apparatus for plating a substrate, comprising: an anode placed to be opposed to the substrate; an electric field regulating member placed between the substrate and the anode, provided with an opening, and equipped with an opening adjustment member configured to change a dimension of the opening; a motor configured to drive the opening adjustment member; and a control device configured to obtain an electric current value or a load factor of the motor, to calculate an amount of change in the load factor of the motor per unit time from the obtained electric current value or the obtained load factor of the motor, and to detect an abnormality of the electric field regulating member when it is detected that the amount of change in the load factor of the motor per unit time exceeds a predetermined threshold value.

One object of the present disclosure is to improve the accuracy of detection of an abnormality of various devices, and/or to advance the timing of detection of an abnormality. There is provided an apparatus for plating a substrate, comprising: an anode placed to be opposed to the substrate; an electric field regulating member placed between the substrate and the anode, provided with an opening, and equipped with an opening adjustment member configured to change a dimension of the opening; a motor configured to drive the opening adjustment member; and a control device configured to obtain an electric current value or a load factor of the motor, to calculate an amount of change in the load factor of the motor per unit time from the obtained electric current value or the obtained load factor of the motor, and to detect an abnormality of the electric field regulating member when it is detected that the amount of change in the load factor of the motor per unit time exceeds a predetermined threshold value.

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.

Provided are composite array electrode, preparation method thereof and use thereof. The composite array electrode comprises a microelectrode array substrate, and a modification layer formed on a surface of a microelectrode of the microelectrode array substrate, wherein the modification layer comprises a plurality of electrically conductive layers arranged at intervals on the surface of the microelectrode, an insulating layer arranged on the surface of the microelectrode except the electrically conductive layers, and wherein material for the electrically conductive layers comprises one or more of nano platinum, nano iridium, conductive polymer and carbon nanotubes. The composite array electrode effectively eliminates the influence of edge effect such that the electric field distributes uniformly on the microelectrode surface of the composite array electrode, significantly improving electrochemical performance and detection capability of the electrode.

Provided are composite array electrode, preparation method thereof and use thereof. The composite array electrode comprises a microelectrode array substrate, and a modification layer formed on a surface of a microelectrode of the microelectrode array substrate, wherein the modification layer comprises a plurality of electrically conductive layers arranged at intervals on the surface of the microelectrode, an insulating layer arranged on the surface of the microelectrode except the electrically conductive layers, and wherein material for the electrically conductive layers comprises one or more of nano platinum, nano iridium, conductive polymer and carbon nanotubes. The composite array electrode effectively eliminates the influence of edge effect such that the electric field distributes uniformly on the microelectrode surface of the composite array electrode, significantly improving electrochemical performance and detection capability of the electrode.