A method for manufacturing a wiring board is capable of forming a metal layer included in a wiring layer to have an even thickness. The method includes preparing a conductive first underlayer on a surface of a substrate; a conductive second underlayer on a surface of the first underlayer; and a seed layer on a surface of the second underlayer and containing metal. The method disposes a solid electrolyte membrane between an anode and the seed layer as a cathode; applies voltage between the anode and the first underlayer to form a metal layer on the surface of the seed layer; removes an exposed portion of the second underlayer without the seed layer from the substrate; and removes an exposed portion of the first underlayer without the seed layer from the substrate. The first underlayer is a material having a higher electrical conductivity than that of the second underlayer.

A plating device includes: an anode; a substrate holder which holds a substrate; a substrate contact which comes into contact with a peripheral edge portion of the substrate; a resistor which is disposed in a way of facing the substrate holder between the anode and the substrate holder, and is used for adjusting ion movement; and a rotation driving mechanism which causes the resistor and the substrate holder to relatively rotate. The resistor includes: a shielding region which forms an outer frame and shields the ion movement between the anode and the substrate; and a resistance region which is formed on the radially inner side of the shielding region, and has a porous structure allowing the passage of an ion. An outer diameter of the resistance region has an amplitude centering on an imaginary reference circle, and has a wave shape which is periodic and annularly continuous.

A plating device includes: an anode; a substrate holder which holds a substrate; a substrate contact which comes into contact with a peripheral edge portion of the substrate; a resistor which is disposed in a way of facing the substrate holder between the anode and the substrate holder, and is used for adjusting ion movement; and a rotation driving mechanism which causes the resistor and the substrate holder to relatively rotate. The resistor includes: a shielding region which forms an outer frame and shields the ion movement between the anode and the substrate; and a resistance region which is formed on the radially inner side of the shielding region, and has a porous structure allowing the passage of an ion. An outer diameter of the resistance region has an amplitude centering on an imaginary reference circle, and has a wave shape which is periodic and annularly continuous.

The invention relates to a distribution system for a process fluid for chemical and/or electrolytic surface treatment of a substrate, a distribution method for a process fluid for chemical and/or electrolytic surface treatment of a substrate and a data processing device. The distribution system for a process fluid for chemical and/or electrolytic surface treatment of a substrate comprises a distribution body and a shield element. The distribution body comprises a plurality of openings for the process fluid. The shield element is configured to at least partially cover at least one of the plurality of openings to limit a flow of the process fluid through the distribution body.

The invention relates to a distribution system for a process fluid for chemical and/or electrolytic surface treatment of a substrate, a distribution method for a process fluid for chemical and/or electrolytic surface treatment of a substrate and a data processing device. The distribution system for a process fluid for chemical and/or electrolytic surface treatment of a substrate comprises a distribution body and a shield element. The distribution body comprises a plurality of openings for the process fluid. The shield element is configured to at least partially cover at least one of the plurality of openings to limit a flow of the process fluid through the distribution body.

An electroplating apparatus includes a plating bath and a substrate in a horizontal direction. The electroplating apparatus further includes a plurality of cathodes on first and second sides of the substrate in a first direction on one surface of the substrate, and an anode above the substrate, the anode being spaced apart from the substrate and configured to be movable in the first direction.

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.

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.

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.