Abstract: Provided is a technique that ensures the suppressed deterioration of plating quality of a substrate due to air bubbles that remain on a surface to be plated of the substrate. A plating apparatus 1000 includes a plating tank 10, a substrate holder 30, a rotation mechanism 40, and an elevating mechanism 50. The plating tank 10 is configured to accumulate a plating solution and include an anode 11 arranged inside the plating tank. The substrate holder 30 is arranged above the anode and configured to hold a substrate as a cathode such that a surface to be plated of the substrate faces downward. The substrate holder includes a ring 31 projecting below an outer peripheral edge of the surface to be plated of the substrate. The rotation mechanism 40 is configured to rotate the substrate holder. The elevating mechanism 50 is configured to elevate the substrate holder. The ring has a lower surface, and at least one protrusion 35 projecting toward a lower side is arranged on a part of the lower surface.

Abstract: Provided is a technique that allows a removal of air bubbles that remain on an ionically resistive element. A plating apparatus 1000 includes a plating tank 10 configured to accumulate a plating solution Ps and including an ionically resistive element 12 arranged in the plating tank, a substrate holder 30 arranged above the ionically resistive element and configured to hold a dummy substrate Wfx, a rotation mechanism 40 configured to rotate the substrate holder, and an elevating mechanism 50 configured to elevate the substrate holder. At least one projecting portion is disposed on a lower surface of the dummy substrate. The at least one projecting portion 60 projects downward from the lower surface. The substrate holder includes a ring 31 projecting below an outer peripheral edge of the lower surface of the dummy substrate. The projecting portion has a lower surface positioned below a lower surface of the ring.

Abstract: Provided is a technique that can suppress remaining of air bubbles on a lower surface of an electric field shielding plate. A plating apparatus 1000 include a plating tank 10, a substrate holder 30, and an electric field shielding plate 60 configured to be arranged in a portion between an anode 50 and a substrate Wf in an inside of the plating tank for shielding a part of an electric field formed between the anode and the substrate. In a top view of the electric field shielding plate, in the inside of the plating tank, an unshielded region 70 that is without shielded by the electric field shielding plate is disposed. An inclined surface is disposed in a lower surface 61a of the electric field shielding plate, the inclined surface is inclined with respect to a horizontal direction and is configured to release an air bubble existing on the lower surface thereof to the unshielded region.

Abstract: A plating module includes a plating tank, a substrate holder, an elevating mechanism, an anode, an ionically resistive element, a supply pipe, and a bypass pipe. The substrate holder is for holding a substrate Wf with a surface to be plated Wf-a facing downward. The elevating mechanism is for moving up and down the substrate holder. The anode is disposed inside the plating tank so as to face the substrate Wf held by the substrate holder. The ionically resistive element is disposed between the anode and the substrate Wf. The supply pipe is for supplying a process liquid stored in a reservoir tank from a lower side of the ionically resistive element to the plating tank. The bypass pipe is for discharging the process liquid supplied to the plating tank via the supply pipe from the lower side of the ionically resistive element to the reservoir tank.

Abstract: An objective of the present invention is to prevent a prewetting liquid from remaining in an edge portion of a substrate. A plating method for subjecting a substrate to a plating treatment is provided, the substrate including a part to be plated that is exposed to a plating solution and an edge portion that is an outer region of the part to be plated. The plating method includes a first sealing step of bringing a first seal body into contact with the substrate to seal the edge portion of the substrate, a prewetting step of subjecting the sealed substrate to a prewetting treatment, a first seal removing step of removing the first seal body from the prewetted substrate, a substrate holding step of holding the substrate with a substrate holder including a second seal body, and a plating step of applying the plating solution to the substrate held by the substrate holder.

Abstract: 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.

Abstract: An objective of the present invention is to prevent a prewetting liquid from remaining in an edge portion of a substrate. A plating method for subjecting a substrate to a plating treatment is provided, the substrate including a part to be plated that is exposed to a plating solution and an edge portion that is an outer region of the part to be plated. The plating method includes a first sealing step of bringing a first seal body into contact with the substrate to seal the edge portion of the substrate, a prewetting step of subjecting the sealed substrate to a prewetting treatment, a first seal removing step of removing the first seal body from the prewetted substrate, a substrate holding step of holding the substrate with a substrate holder including a second seal body, and a plating step of applying the plating solution to the substrate held by the substrate holder.

Abstract: A technique that ensures suppressing deterioration of a plating quality of a substrate caused by air bubbles accumulated on a lower surface of a membrane is provided. An air bubble removing method of a plating apparatus is an air bubble removing method for removing air bubble in an anode chamber 13 in a plating apparatus 1000 including a plating tank 10 and a substrate holder 30. The air bubble removing method includes: supplying a plating solution Ps from at least one supply port 70 disposed in an outer peripheral portion 12 of the anode chamber to the anode chamber and causing at least one discharge port 71 disposed in the outer peripheral portion of the anode chamber so as to face the supply port to suction the supplied plating solution to form a shear flow Sf of the plating solution along a lower surface on the lower surface 61a of a membrane 61 in the anode chamber.

Abstract: Provided is a technique that can suppress remaining of air bubbles on a lower surface of an electric field shielding plate. A plating apparatus 1000 include a plating tank 10, a substrate holder 30, and an electric field shielding plate 60 configured to be arranged in a portion between an anode 50 and a substrate Wf in an inside of the plating tank for shielding a part of an electric field formed between the anode and the substrate. In a top view of the electric field shielding plate, in the inside of the plating tank, an unshielded region 70 that is without shielded by the electric field shielding plate is disposed. An inclined surface is disposed in a lower surface 61a of the electric field shielding plate, the inclined surface is inclined with respect to a horizontal direction and is configured to release an air bubble existing on the lower surface thereof to the unshielded region.

Abstract: A plating module includes a plating tank, a substrate holder, an elevating mechanism, an anode, an ionically resistive element, a supply pipe, and a bypass pipe. The substrate holder is for holding a substrate Wf with a surface to be plated Wf-a facing downward. The elevating mechanism is for moving up and down the substrate holder. The anode is disposed inside the plating tank so as to face the substrate Wf held by the substrate holder. The ionically resistive element is disposed between the anode and the substrate Wf. The supply pipe is for supplying a process liquid stored in a reservoir tank from a lower side of the ionically resistive element to the plating tank. The bypass pipe is for discharging the process liquid supplied to the plating tank via the supply pipe from the lower side of the ionically resistive element to the reservoir tank.

Abstract: A resistance measuring module for measuring electric resistance of a substrate holder is provided. The substrate holder has an electric contact configured to feed a current to a held substrate and contactable with the substrate. The substrate holder is able to hold a testing substrate for measurement of electric resistance of the substrate holder, and is configured such that the electric contact comes into contact with the testing substrate in a state where the testing substrate is held. The resistance measuring module includes: a test probe contactable with the testing substrate held in the substrate holder; and a resistance measuring instrument for measurement of a resistance value between the electric contact and the probe via the testing substrate.

Abstract: 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.

Abstract: A resistance measuring module for measuring electric resistance of a substrate holder is provided. The substrate holder has an electric contact configured to feed a current to a held substrate and contactable with the substrate. The substrate holder is able to hold a testing substrate for measurement of electric resistance of the substrate holder, and is configured such that the electric contact comes into contact with the testing substrate in a state where the testing substrate is held. The resistance measuring module includes: a test probe contactable with the testing substrate held in the substrate holder; and a resistance measuring instrument for measurement of a resistance value between the electric contact and the probe via the testing substrate.