Electroplating systems according to embodiments of the present technology may include a plating chamber configured to deposit metal material onto substrates positioned in the plating chamber. The plating chamber may include a rotor and a vessel. The electroplating systems may include at least one of baffle positioned in the plating chamber. The at least one baffle may define a plurality of slots. The at least one baffle may be configured to limit or prevent fluid from splashing the rotor or the plating chamber during operation of the plating chamber.

Provided is a plating apparatus that allows cleaning a contact cleaning member.

The plating apparatus includes: a plating tank configured to house a plating solution; a substrate holder configured to hold a substrate with a surface to be plated facing downward, the substrate holder including a contact member for feeding power to the substrate; a contact cleaning member 482 for discharging a cleaning liquid to the contact member while the contact cleaning member is at a cleaning position between the plating tank and the substrate holder; a driving mechanism 476 configured to move the contact cleaning member 482 between the cleaning position and a retracted position retracted from between the plating tank and the substrate holder; and a nozzle cleaning cover 489 configured to cover an upper portion of the contact cleaning member 482 while the contact cleaning member 482 is at the retracted position.

Provided is a plating apparatus that allows cleaning a contact cleaning member.

The plating apparatus includes: a plating tank configured to house a plating solution; a substrate holder configured to hold a substrate with a surface to be plated facing downward, the substrate holder including a contact member for feeding power to the substrate; a contact cleaning member 482 for discharging a cleaning liquid to the contact member while the contact cleaning member is at a cleaning position between the plating tank and the substrate holder; a driving mechanism 476 configured to move the contact cleaning member 482 between the cleaning position and a retracted position retracted from between the plating tank and the substrate holder; and a nozzle cleaning cover 489 configured to cover an upper portion of the contact cleaning member 482 while the contact cleaning member 482 is at the retracted position.

The present disclosure is directed to a fluid head that is configured to eject a first fluid (e.g., a liquid state fluid) and a second fluid (e.g., a gaseous state fluid). The fluid head is movable in a rotatable-fashion and a translatable-fashion such that the fluid head may be utilized to increase a speed and decrease a period of time for cleaning and drying a workpiece after an electro-chemical polishing (ECP) process or step. The fluid head may also be utilized to increase a speed and decrease a period of time for beveling an edge of a conductive layer on the workpiece. The present disclosure is also directed to methods for cleaning and drying the workpiece as well as beveling the conductive layer of the workpiece utilizing the fluid head.

The present disclosure is directed to a fluid head that is configured to eject a first fluid (e.g., a liquid state fluid) and a second fluid (e.g., a gaseous state fluid). The fluid head is movable in a rotatable-fashion and a translatable-fashion such that the fluid head may be utilized to increase a speed and decrease a period of time for cleaning and drying a workpiece after an electro-chemical polishing (ECP) process or step. The fluid head may also be utilized to increase a speed and decrease a period of time for beveling an edge of a conductive layer on the workpiece. The present disclosure is also directed to methods for cleaning and drying the workpiece as well as beveling the conductive layer of the workpiece utilizing the fluid head.

Provided is a technique that allows ensuring a downsized plating apparatus. A plating apparatus includes a discharge module 50. The discharge module includes a module main body 51 including a plurality of nozzles 52 configured to discharge a process liquid upward, and a moving mechanism 60 including a rotation shaft 61 disposed at a side of a plating tank and connected to the module main body. The moving mechanism 60 moves the module main body by rotation of the rotation shaft. The moving mechanism moves the module main body between the first position and the second position. The plurality of nozzles are arranged such that the process liquid discharged from the plurality of nozzles is brought in contact with a lower surface of a substrate from a center portion to an outer peripheral edge portion when the module main body moves to the second position. The module main body further includes a recovery member configured to recover the process liquid dropped after being discharged from the plurality of nozzles and brought in contact with the lower surface of the substrate.

Plating bath and well structures and methods are described to stop the organic compounds present in plating reservoir wells or bath solution from rising, i.e., climbing up the reservoir wall. An electroplating apparatus includes a vessel holding a liquid solution including metal plating material and an organic species, and a method of operating an electroplating apparatus. The apparatus is designed with plating bath and structures and methods to stop the organic compounds present in plating reservoir wells or bath solution from rising, i.e., climbing or wicking up the inner surfaces of reservoir walls, and to wash them back down on a continuous or cyclical basis in order to maintain a concentration of organic compounds in the plating solution within upper and lower specification limits.

Plating bath and well structures and methods are described to stop the organic compounds present in plating reservoir wells or bath solution from rising, i.e., climbing up the reservoir wall. An electroplating apparatus includes a vessel holding a liquid solution including metal plating material and an organic species, and a method of operating an electroplating apparatus. The apparatus is designed with plating bath and structures and methods to stop the organic compounds present in plating reservoir wells or bath solution from rising, i.e., climbing or wicking up the inner surfaces of reservoir walls, and to wash them back down on a continuous or cyclical basis in order to maintain a concentration of organic compounds in the plating solution within upper and lower specification limits.

Plating bath and well structures and methods are described to stop the organic compounds present in plating reservoir wells or bath solution from rising, i.e., climbing up the reservoir wall. An electroplating apparatus includes a vessel holding a liquid solution including metal plating material and an organic species, and a method of operating an electroplating apparatus. The apparatus is designed with plating bath and structures and methods to stop the organic compounds present in plating reservoir wells or bath solution from rising, i.e., climbing or wicking up the inner surfaces of reservoir walls, and to wash them back down on a continuous or cyclical basis in order to maintain a concentration of organic compounds in the plating solution within upper and lower specification limits.

Plating bath and well structures and methods are described to stop the organic compounds present in plating reservoir wells or bath solution from rising, i.e., climbing up the reservoir wall. An electroplating apparatus includes a vessel holding a liquid solution including metal plating material and an organic species, and a method of operating an electroplating apparatus. The apparatus is designed with plating bath and structures and methods to stop the organic compounds present in plating reservoir wells or bath solution from rising, i.e., climbing or wicking up the inner surfaces of reservoir walls, and to wash them back down on a continuous or cyclical basis in order to maintain a concentration of organic compounds in the plating solution within upper and lower specification limits.