The present disclosure provides a plating apparatus that can determine an acceleration at the time of an inappropriate deceleration of a transfer device that may cause contact between a substrate holder and a processing tank, a control method for a plating apparatus, and a storage medium storing a program. The plating apparatus according to the present disclosure includes a transfer device including an imaging device, the processing tank having an opening, a reference mark, and a control device, the control device is configured to be able to execute a test at a test acceleration, and the test includes: controlling, by the control device, the imaging device to capture a reference image when the transfer device is located at a determination position directly above the processing tank; moving the transfer device from a reference position to the determination position; controlling the imaging device to capture a comparison video when and after the transfer device stops; and determining, based on the reference image and the comparison video, whether the lower end portion of the substrate holder protrudes outside a region where the opening is extended in a vertical direction, to determine that the test acceleration has an inappropriate value when the lower end portion protrudes outside the region.

Uniformity in plated film thickness in a plating apparatus is improved. A plating apparatus for plating a substrate by making electric current flow from an anode to the substrate is provided. The plating apparatus comprises: plural anode-side electric wires which are electrically connected to the anode via plural electric contacts on the anode; plural substrate-side electric wires which are electrically connected to the substrate via plural electric contacts on the substrate; plural variable resistors positioned, in at least one of the anode side and the substrate side, in middle positions in the plural anode-side electric wires or the plural substrate-side electric wires; and a controller constructed to adjust each of resistance values of the plural variable resistors.

To partially or locally control a plating film thickness on a polygonal substrate. There is provided a regulation plate for adjusting a current between an anode and the polygonal substrate. This regulation plate includes a main body that has an edge forming a polygonal opening through which the current passes and an attachable/detachable shielding member to shield at least a part of the polygonal opening.

A leak check method includes: performing a first inspection of measuring a pressure in an internal space formed by a seal of the substrate holder, while evacuating the internal space, and detecting that the pressure reaches a first pressure threshold value within a predetermined first inspection time; performing a second inspection of closing the internal space that has been evacuated, measuring the pressure in the closed internal space, and detecting that the pressure in the closed internal space does not exceed a second pressure threshold value within a predetermined second inspection time; and performing a third inspection of measuring a pressure difference between the pressure in the closed internal space and a vacuum pressure in a master container, and detecting that an amount of increase in the pressure difference within a predetermined third inspection time is kept equal to or below a pressure difference threshold value.

Various embodiments herein relate to methods and apparatus for electroplating metal onto substrates. In various cases, a reference electrode may be modified to promote improved electroplating results. The modifications may relate to one or more of the reference electrode's shape, position, relative conductivity compared to the electrolyte, or other design feature. In some particular examples the reference electrode may be dynamically changeable, for example having a changeable shape and/or position. In a particular example the reference electrode may be made of multiple segments. The techniques described herein may be combined as desired for individual applications.

An electroplating apparatus including an anode and a cathode, a power supply, and a regulating plate is provided. The power supply is electrically connected to the anode and the cathode. The regulating plate is arranged between the anode and the cathode. The regulating plate includes an insulating grid plate and a plurality of magnetic components. The plurality of magnetic components are uniformly and randomly arranged on the insulating grid plate. An electroplating method is also provided.

Electroplating methods and systems are described that include adding a metal-ion-containing starting solution to a catholyte to increase a metal ion concentration in the catholyte to a first metal ion concentration. The methods and systems further include measuring the metal ion concentration in the catholyte while the metal ions electroplate onto a substrate and the catholyte reaches a second metal ion concentration that is less than the first metal ion concentration. The methods and systems additionally include adding a portion of an anolyte directly to the catholyte when the catholyte reaches the second metal ion concentration. The addition of the portion of the anolyte increases the metal ion concentration in the catholyte to a third metal ion concentration that is greater than or about the first metal ion concentration.

A wafer plating fixture for use in simultaneously electroplating a two substrates. The wafer plating fixture including: an electrically conductive carrier bus; a plurality of contact clips electrically coupled to the carrier bus and configured to hold the two substrates in place and electrically couple the two substrates to the carrier bus; and a non-conductive substrate backer to separate the two substrates coupled to the carrier bus. A method of electroplating a plurality of substrates. The method including: mounting two substrates to be plated onto a wafer plating fixture; mounting the wafer plating fixture on a continuous belt of plating system; dipping the wafer plating fixture with the two substrates held thereon into an electroplating bath; and applying a voltage to the two substrates via the wafer plating fixture.

The disclosure relates to a distribution system for a process fluid for chemical and/or electrolytic surface treatment of a rotatable substrate, an electrochemical deposition system for a chemical and/or electrolytic surface treatment of a substrate and a method for a chemical and/or electrolytic surface treatment of a substrate in a process fluid. The distribution system comprises a distribution body. The distribution body comprises a plurality of openings for the process fluid. The openings are arranged in a spiral-shaped pattern on a surface of the distribution body.

Systems and methods for electroplating are described. The electroplating system may include a vessel configured to hold a first portion of a liquid electrolyte. The system may also include a substrate holder configured for holding a substrate in the vessel. The system may further include a first reservoir in fluid communication with the vessel. In addition, the system may include a second reservoir in fluid communication with the vessel. Furthermore, the system may include a first mechanism configured to expel a second portion of the liquid electrolyte from the first reservoir into the vessel. The system may also include a second mechanism configured to take in a third potion of the liquid electrolyte from the vessel into the second reservoir when the second portion of the liquid electrolyte is expelled from the first reservoir. Methods may include oscillating flow of the electrolyte within the vessel.