The agitation of the plating solution may result in spattering of the plating solution. It have been found that the spattered plating solution can be attached even to portions that are not originally brought into contact with the plating solution in the plating apparatus. There is provided an electroplating apparatus for plating a substrate using a substrate holder, the electroplating apparatus comprising at least one bath for storing the substrate, the substrate holder being provided with a hanger shoulder, and a holder contact, and wherein the electroplating apparatus being provided with a cleaning/drying part provided on at least one side of the bath, the cleaning/drying part being provided for cleaning and/or drying at least one of the hanger shoulder, the holder contact and a contact provided to the bath.

The agitation of the plating solution may result in spattering of the plating solution. It have been found that the spattered plating solution can be attached even to portions that are not originally brought into contact with the plating solution in the plating apparatus. There is provided an electroplating apparatus for plating a substrate using a substrate holder, the electroplating apparatus comprising at least one bath for storing the substrate, the substrate holder being provided with a hanger shoulder, and a holder contact, and wherein the electroplating apparatus being provided with a cleaning/drying part provided on at least one side of the bath, the cleaning/drying part being provided for cleaning and/or drying at least one of the hanger shoulder, the holder contact and a contact provided to the bath.

A plating apparatus 1 includes a substrate holder 10, a first electrode, a second electrode and a voltage applying unit 30. The substrate holder 10 is configured to hold a substrate. The first electrode is electrically connected to the substrate. The second electrode is configured to scan with respect to a front surface of the substrate. The voltage applying unit 30 is configured to apply a voltage between the first electrode and the second electrode. A first discharge opening 23 configured to discharge a plating liquid L1 and a second discharge opening 24 configured to discharge a cleaning liquid L2 are formed in a bottom surface 22a of the second electrode.

A plating apparatus 1 includes a substrate holder 10, a first electrode, a second electrode and a voltage applying unit 30. The substrate holder 10 is configured to hold a substrate. The first electrode is electrically connected to the substrate. The second electrode is configured to scan with respect to a front surface of the substrate. The voltage applying unit 30 is configured to apply a voltage between the first electrode and the second electrode. A first discharge opening 23 configured to discharge a plating liquid L1 and a second discharge opening 24 configured to discharge a cleaning liquid L2 are formed in a bottom surface 22a of the second electrode.

Provided herein are methods and systems for electrolytic processing of metallic substrates, such as aluminum alloys. The disclosure provides methods of making an anodized substrate by anodizing a metallic substrate in an electrolyte solution comprising phosphoric acid. In particular, the disclosure describes various conditions for anodizing the metallic substrate, including temperature, acid concentration, and voltage. The disclosure also provides systems for carrying out described methods.

Provided herein are methods and systems for electrolytic processing of metallic substrates, such as aluminum alloys. The disclosure provides methods of making an anodized substrate by anodizing a metallic substrate in an electrolyte solution comprising phosphoric acid. In particular, the disclosure describes various conditions for anodizing the metallic substrate, including temperature, acid concentration, and voltage. The disclosure also provides systems for carrying out described methods.

An electroplating apparatus includes: an electroplating bath including an anode region, in which an anode electrode is arranged, a cathode region and a membrane; a head unit including a contact ring holding a wafer and configured so that a first cathode potential is applied to the contact ring during an electroplating process; a reverse potential electrode arranged adjacent to the membrane and configured so that a second cathode potential is applied to the reverse potential electrode during the electroplating process, and a reverse cathode potential is applied to the reverse potential electrode during a rinsing process, and a power supply unit configured to apply the first cathode potential and the second cathode potential during the electroplating process, and further configured to apply the reverse cathode potential and a reverse anode potential to the anode electrode during the rinsing process.

An electroplating apparatus includes: an electroplating bath including an anode region, in which an anode electrode is arranged, a cathode region and a membrane; a head unit including a contact ring holding a wafer and configured so that a first cathode potential is applied to the contact ring during an electroplating process; a reverse potential electrode arranged adjacent to the membrane and configured so that a second cathode potential is applied to the reverse potential electrode during the electroplating process, and a reverse cathode potential is applied to the reverse potential electrode during a rinsing process, and a power supply unit configured to apply the first cathode potential and the second cathode potential during the electroplating process, and further configured to apply the reverse cathode potential and a reverse anode potential to the anode electrode during the rinsing process.

A method of cleaning a conducting film containing tin oxide from an insulating surface of an item for use in electroplating applications, comprises the steps of immersing the item in a cleaning fluid and irradiating the immersed item with light of wavelength in the range 100 nm-450 nm.

Provided is a film forming apparatus and a film forming method for forming a metal film capable of reducing the occurrence of discoloring or alteration of the metal film caused by drying of an electrolytic solution remaining on the surface of the formed metal film. A space where the metal film exists is sealed between a housing and a mount base in a state where the solid electrolyte membrane is in contact with the metal film. The film forming apparatus includes a water supply unit supplying a wash water to the sealed space such that the wash water flows onto the surface of the metal film being in contact with the solid electrolyte membrane, and a water discharge unit discharging a wash water from the sealed space such that the wash water having flown onto the surface of the metal film flows out from the surface of the metal film.