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.

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.

Electroplating processing systems according to the present technology may include a recirculating tank containing a first volume of processing fluid. The recirculating tank may be fluidly coupled with a delivery pump. The systems may include a vessel configured to receive the processing fluid from the pump. The vessel may include an inner chamber and an outer chamber, and the inner chamber may be sized to hold a second volume of processing fluid less than the first volume of processing fluid. A liquid level sensor may be associated with the vessel to provide a liquid level indication in the outer chamber. The systems may include a return line coupled with an outlet of the vessel and coupled with an inlet of the recirculating tank. The systems may also include a return pump fluidly coupled with the return line. The return pump may be electrically coupled with the liquid level sensor.

Electroplating processing systems according to the present technology may include a recirculating tank containing a first volume of processing fluid. The recirculating tank may be fluidly coupled with a delivery pump. The systems may include a vessel configured to receive the processing fluid from the pump. The vessel may include an inner chamber and an outer chamber, and the inner chamber may be sized to hold a second volume of processing fluid less than the first volume of processing fluid. A liquid level sensor may be associated with the vessel to provide a liquid level indication in the outer chamber. The systems may include a return line coupled with an outlet of the vessel and coupled with an inlet of the recirculating tank. The systems may also include a return pump fluidly coupled with the return line. The return pump may be electrically coupled with the liquid level sensor.

An object is to precisely grasping, in real time, film thickness of a plated film during a plating process. A plating apparatus comprises: a plating tank for storing plating liquid; a substrate holder for holding a substrate; an anode arranged in the plating tank in such a manner that it faces the substrate held by the substrate holder; an electric potential sensor constructed in such a manner that it is arranged in a position close to the substrate held by the substrate holder, and measures electric potential of the plating liquid; and a state space model constructed to estimate current density of current flowing through an outer edge part of the substrate, based on a measured value of electric potential of the plating liquid obtained by the electric potential sensor and by using a state equation and an observation equation.

An object is to precisely grasping, in real time, film thickness of a plated film during a plating process. A plating apparatus comprises: a plating tank for storing plating liquid; a substrate holder for holding a substrate; an anode arranged in the plating tank in such a manner that it faces the substrate held by the substrate holder; an electric potential sensor constructed in such a manner that it is arranged in a position close to the substrate held by the substrate holder, and measures electric potential of the plating liquid; and a state space model constructed to estimate current density of current flowing through an outer edge part of the substrate, based on a measured value of electric potential of the plating liquid obtained by the electric potential sensor and by using a state equation and an observation equation.

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.

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.

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.

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.