An electroplating device for electroplating an alloy comprising a plurality of metals on a workpiece includes an electroplating bath, a plurality of groups of anodes, and a power supply device. The electroplating bath contains an electroplating solution in which the workpiece as a cathode is at least partially immersed. Each of the plurality of groups of anodes provides at least one metal required for electroplating. An electrolytic potential of at least one metal of each group of anodes is distinct from that of at least one metal of any other group of anodes. The power supply device adjusts the proportion of current transmitted to each group of anodes according to the proportion of the metals in the alloy.

An electroplating method and a system for electrolytically coating a steel strip, in particular for the automotive sector, with a coating based on zinc and/or a zinc alloy utilizes pulse technology.

An electroplating device includes an electroplating bath containing an electroplating solution into which a workpiece to be electroplated as a cathode is at least partially immersed, a first anode provided in the electroplating bath, and a liquid spraying device. The liquid spraying device includes a main body part having at least one inlet for conveying the electroplating solution into the main body part, and a plurality of nozzles installed on the main body part. At least part of the nozzles are positioned such that a flow direction of the electroplating solution ejected from the nozzle is substantially parallel to a direction of a power line formed by the first anode and the cathode.

A plating apparatus for electroplating a wafer includes a housing defining a plating chamber for housing a plating solution. A voltage source of the apparatus has a first terminal having a first polarity and a second terminal having a second polarity different than the first polarity. The first terminal is electrically coupled to the wafer. An anode is within the plating chamber, and the second terminal is electrically coupled to the anode. A membrane support is within the plating chamber and over the anode. The membrane support defines apertures, wherein in a first zone of the membrane support a first aperture-area to surface-area ratio is a first ratio, and in a second zone of the membrane support a second aperture-area to surface-area ratio is a second ratio, different than the first ratio.

An electroplating device for electroplating an alloy comprising a plurality of metals on a workpiece includes an electroplating bath, a plurality of groups of anodes, and a power supply device. The electroplating bath contains an electroplating solution in which the workpiece as a cathode is at least partially immersed. Each of the plurality of groups of anodes provides at least one metal required for electroplating. An electrolytic potential of at least one metal of each group of anodes is distinct from that of at least one metal of any other group of anodes. The power supply device adjusts the proportion of current transmitted to each group of anodes according to the proportion of the metals in the alloy.

A semiconductor device manufacturing jig for electroplating a substrate includes a conductive member. The substrate includes an inner part including a first surface, and an outer rim part surrounding the inner part. The outer rim part has a ring shape that protrudes further than the first surface in a direction perpendicular to the first surface. The conductive member causes a current to flow in the inner part by contacting a portion of the first surface of the inner part without contacting the outer rim part.

Systems for masking and sealing a component for surface treatment. A system includes a pair of fixture plates disposed on opposite ends of the component from each other. One or more inner sleeves are inserted into the component to mask and seal at least a portion of the component. An outer sleeve extends between the fixture plates to seal outside of the component. A pair of fixture rods extend between the first and second fixture plates and couple the first and second fixture plates together. The system is configured to effect surface treatment of an exposed area of the component, at least a portion of the exposed area defined by and disposed adjacent to the one or more inner sleeves.

One embodiment relates to a substrate carrier for use in electroplating a plurality of substrates. The substrate carrier comprises a non-conductive carrier body on which the substrates are to be held. Electrically-conductive lines are embedded within the carrier body, and a plurality of contact clips are coupled to the electrically-conductive lines embedded within the carrier body. The contact clips hold the substrates in place and electrically couple the substrates to the electrically-conductive lines. The non-conductive carrier body is continuous so as to be impermeable to flow of electroplating solution through the non-conductive carrier body. Other embodiments, aspects and features are also disclosed.

Tungsten-containing metal films may be deposited in recessed features of semiconductor substrates by electrodeposition. The tungsten-containing metal film is electrodeposited under conditions so that the tunsten-containing metal film is free or substantially free of oxide. Conditions are optimized during electrodeposition for pH, tungsten concentration, and current density, among other parameters. The tungsten-containing metal film may include cobalt tungsten alloy, cobalt nickel tungsten alloy, or nickel tungsten alloy, where a tungsten content in the tungsten-containing metal film is between about 1-20 atomic %.

Systems for masking and sealing a component for surface treatment. A system includes a pair of fixture plates disposed on opposite ends of the component from each other. One or more inner sleeves are inserted into the component to mask and seal at least a portion of the component. An outer sleeve extends between the fixture plates to seal outside of the component. A pair of fixture rods extend between the first and second fixture plates and couple the first and second fixture plates together. The system is configured to effect surface treatment of an exposed area of the component, at least a portion of the exposed area defined by and disposed adjacent to the one or more inner sleeves.