There is provided a substrate holder. The substrate holder comprises a contact assembly; a first plate configured to hold a substrate between the contact assembly and the first plate; at least one first pin fixed to the contact assembly, extended toward a first plate side on outside of the substrate, and provided with a locked portion; a locking member placed on a side opposite to the contact assembly relative to the first plate and configured to be displaceable between a locked state and an unlocked state with respect to the locked portion of the first pin; and at least one first biasing member placed between the locking member and the first plate along an outer circumferential part of the substrate such as to separate the locking member and the first plate from each other and compressed between the locking member and the first plate in the locked state to bias the first plate toward the contact assembly.

There is provided a substrate holder. The substrate holder comprises a contact assembly; a first plate configured to hold a substrate between the contact assembly and the first plate; at least one first pin fixed to the contact assembly, extended toward a first plate side on outside of the substrate, and provided with a locked portion; a locking member placed on a side opposite to the contact assembly relative to the first plate and configured to be displaceable between a locked state and an unlocked state with respect to the locked portion of the first pin; and at least one first biasing member placed between the locking member and the first plate along an outer circumferential part of the substrate such as to separate the locking member and the first plate from each other and compressed between the locking member and the first plate in the locked state to bias the first plate toward the contact assembly.

In a plating method for mounting a tubular workpiece having openings at both ends in an axial direction thereof on a power feeding clip and immersing the tubular workpiece in a circulated plating solution to plate the tubular workpiece, the mounting of the tubular workpiece on the power feeding clip is performed by inserting the power feeding clip into the tubular workpiece from one of the openings of the tubular workpiece. The power feeding clip is configured by a folded metal plate, and includes a plurality of elastic contact pieces that can elastically contact the inner surface of the tubular workpiece to hold the tubular workpiece and supply power to the tubular workpiece, and a restraining part that is located inside the tubular workpiece and restrains flow of the plating solution in the axial direction.

An electroplating apparatus for electroplating metal on a substrate includes a plating chamber configured to contain an electrolyte, a substrate holder configured to hold and rotate the substrate during electroplating, an anode, and an azimuthally asymmetric auxiliary electrode configured to be biased both anodically and cathodically during electroplating. The azimuthally asymmetric auxiliary electrode (which may be, for example, C-shaped), can be used for controlling azimuthal uniformity of metal electrodeposition by donating and diverting ionic current at a selected azimuthal position. In another aspect, an electroplating apparatus for electroplating metal includes a plating chamber configured to contain an electrolyte, a substrate holder configured to hold and rotate the substrate during electroplating, an anode, a shield configured to shield current at the periphery of the substrate; and an azimuthally asymmetric auxiliary anode configured to donate current to the shielded periphery of the substrate at a selected azimuthal position on the substrate.

An electroplating apparatus for electroplating metal on a substrate includes a plating chamber configured to contain an electrolyte, a substrate holder configured to hold and rotate the substrate during electroplating, an anode, and an azimuthally asymmetric auxiliary electrode configured to be biased both anodically and cathodically during electroplating. The azimuthally asymmetric auxiliary electrode (which may be, for example, C-shaped), can be used for controlling azimuthal uniformity of metal electrodeposition by donating and diverting ionic current at a selected azimuthal position. In another aspect, an electroplating apparatus for electroplating metal includes a plating chamber configured to contain an electrolyte, a substrate holder configured to hold and rotate the substrate during electroplating, an anode, a shield configured to shield current at the periphery of the substrate; and an azimuthally asymmetric auxiliary anode configured to donate current to the shielded periphery of the substrate at a selected azimuthal position on the substrate.

A cartridge assembly, a jig, a jig assembly and an apparatus for electroless plating are disclosed. The cartridge includes a first cartridge and a second cartridge. The first cartridge includes a holder disposed at a corner thereof, and the holder is formed to protrude toward the second cartridge. The second cartridge includes an accommodating portion disposed at a corner thereof, and the accommodating portion accommodates at least a portion of the holder.

Provided are cleaning methods and systems to remove unintended metallic deposits from electroplating apparatuses using reverse current deplating techniques. Such cleaning involves positioning a cleaning (deplating) disk in an electroplating cup similar to a regular processed substrate. The front surface of the cleaning disk includes a corrosion resistant conductive material to form electrical connections to deposits on the cup's surfaces. The disk is sealed in the cup and submerged into a plating solution. A reverse current is then applied to the front conductive surface of the disk to initiate deplating of the deposits. Sealing compression in the cup may change during cleaning to cause different deformation of the lip seal and to form new electrical connections to the deposits. The proposed cleaning may be applied to remove deposits formed during electroplating of alloys, in particular, tin-silver alloys widely used for semiconductor and wafer level packaging.

Provided are cleaning methods and systems to remove unintended metallic deposits from electroplating apparatuses using reverse current deplating techniques. Such cleaning involves positioning a cleaning (deplating) disk in an electroplating cup similar to a regular processed substrate. The front surface of the cleaning disk includes a corrosion resistant conductive material to form electrical connections to deposits on the cup's surfaces. The disk is sealed in the cup and submerged into a plating solution. A reverse current is then applied to the front conductive surface of the disk to initiate deplating of the deposits. Sealing compression in the cup may change during cleaning to cause different deformation of the lip seal and to form new electrical connections to the deposits. The proposed cleaning may be applied to remove deposits formed during electroplating of alloys, in particular, tin-silver alloys widely used for semiconductor and wafer level packaging.

There is provided a substrate holder configured to hold a substrate, the substrate holder comprising: a first holding member; and a second holding member configured to hold the substrate between the first holding member and the second holding member, wherein the first holding member comprises: at least one substrate contact arranged to come into contact with the substrate; at least one seal member provided with a first seal portion configured to cover periphery of a leading end portion of one or a plurality of the substrate contacts; and at least one bus bar electrically connected with the one or plurality of substrate contacts and provided with one or a plurality of first through holes to receive the first seal portion, wherein the leading end portion of the one or plurality of substrate contacts is arranged to pass through the first through hole from a side opposite to the second holding member toward the second holding member and is fixed to the bus bar in a state that the periphery of the leading end portion of the one or plurality of substrate contacts is covered by the first seal portion.

There is provided a substrate holder configured to hold a substrate, the substrate holder comprising: a first holding member; and a second holding member configured to hold the substrate between the first holding member and the second holding member, wherein the first holding member comprises: at least one substrate contact arranged to come into contact with the substrate; at least one seal member provided with a first seal portion configured to cover periphery of a leading end portion of one or a plurality of the substrate contacts; and at least one bus bar electrically connected with the one or plurality of substrate contacts and provided with one or a plurality of first through holes to receive the first seal portion, wherein the leading end portion of the one or plurality of substrate contacts is arranged to pass through the first through hole from a side opposite to the second holding member toward the second holding member and is fixed to the bus bar in a state that the periphery of the leading end portion of the one or plurality of substrate contacts is covered by the first seal portion.