A substrate processing apparatus includes a holding device that includes a conductive member and holds a substrate, a conduction path structure that includes a conductive material and positioned such that the conduction path structure is in contact with the holding device, a supply device that supplies a processing liquid to the substrate held by the holding device, and a grounding structure including a variable resistance device that changes a resistance such that the grounding structure has a first end portion connected the conduction path structure and a second end portion connected to a ground potential.

Systems for electroplating seal inspection may include a module configured to support a seal for inspection. The module may include a set of supports positioned to contact an interior rim of the seal. The module may be configured to rotate the seal about a central axis. The system may also include a detector positioned on the module. The detector may be positioned to scan an exterior surface of the seal.

A method comprises depositing a barrier layer on a dielectric layer to prevent oxidation of a metal layer to be deposited by electroplating due to an oxide present in the dielectric layer and depositing a doped liner layer on the barrier layer to bond with the metal layer to be deposited on the liner layer by the electroplating. The dopant forms a protective passivation layer on a surface of the liner layer and dissolves during the electroplating so that the metal layer deposited on the liner layer by the electroplating bonds with the liner layer. The dopant reacts with the dielectric layer and forms a layer of a compound between the barrier layer and the dielectric layer. The compound layer prevents oxidation of the barrier layer and the liner layer due to the oxide present in the dielectric layer and adheres the barrier layer to the dielectric layer.

A calculation amount and calculation time for a substrate conveyance schedule are reduced. A scheduler is provided which is incorporated in a control section of a substrate processing apparatus including a plurality of substrate processing sections that process a substrate, a conveyance section that conveys the substrate, and the control section that controls the conveyance section and the substrate processing sections, and calculates a substrate conveyance schedule. The scheduler includes: a modeling section that models processing conditions, processing time and constraints of the substrate processing apparatus into nodes and edges using a graph network theory, prepares a graph network, and calculates a longest route length to each node; and a calculation section that calculates the substrate conveyance schedule based on the longest route length.

The present invention provides a substrate holding member comprising: a first holding member; a second holding member that cooperates with the first holding member to hold the substrate therebetween; and a transparent portion provided in at least one of the first and second holding members.

A substrate holder has a first holding member having a first surface configured to contact with a substrate, and a second holding member for sandwiching and holding the substrate together with the first holding member. The first holding member has a positioning member for positioning the substrate in contact with the first surface at a prescribed position of the first surface. The positioning member is configured to move between a first position where the substrate is to be positioned at the prescribed position of the first surface, in contact with a peripheral edge part of the substrate, and a second position not in contact with the substrate. The second holding member has a driving member configured to cause the positioning member to be positioned at the first position, at the time when holding the substrate by the first holding member and the second holding member.

The invention relates to a device and a method for continuous production of porous silicon layers (single or multiple layers) on workpieces made of silicon or workpieces with a silicon coating. The method according to the invention is thereby based on a one-sided etching method, the workpiece being guided horizontally, by means of a transport device, with the front side of the workpiece to be etched, past at least one etching chamber, comprising an electrolyte and a cathode. This method can be used in particular for the production of PV cells.

In one implementation a cathode for electrochemical metal removal has a generally disc-shaped body and a plurality of channels in the generally disc-shaped body, where the channels are configured for passing electrolyte through the body of the cathode. The channels may be fitted with non-conductive (e.g., plastic) tubes that in some embodiments extend above the body of the cathode to a height of at least 1 cm. The cathode may also include a plurality of indentations at the edge to facilitate electrolyte flow at the edge of the cathode. In some embodiments the cathode includes a plurality of non-conductive fixation elements on a conductive surface of the cathode, where the fixation elements are attachable to one or more handles for removing the cathode from the electrochemical metal removal apparatus.

An inspection apparatus, a plating apparatus, and an appearance inspection apparatus that are capable of automatically inspecting a substrate holder are provided. An inspection apparatus that includes an electric contact configured to contact a substrate to allow current flow to the substrate and a sealing member configured to seal a surface of the substrate and that inspects a substrate holder holding the substrate is provided. The inspection apparatus includes a stocker installation part in which a stocker configured to house the substrate holder is installed, a cleaning device configured to cleanse the substrate holder, a substrate attaching/detaching device configured to open and close the substrate holder, an appearance inspection apparatus configured to acquire image data or shape data of appearance of at least one of the sealing member and the electric contact, and a conveyer configured to convey the substrate holder among the stocker, the cleaning device, and the appearance inspection apparatus.

A method comprises depositing a barrier layer on a dielectric layer to prevent oxidation of a metal layer to be deposited by electroplating due to an oxide present in the dielectric layer and depositing a doped liner layer on the barrier layer to bond with the metal layer to be deposited on the liner layer by the electroplating. The dopant forms a protective passivation layer on a surface of the liner layer and dissolves during the electroplating so that the metal layer deposited on the liner layer by the electroplating bonds with the liner layer. The dopant reacts with the dielectric layer and forms a layer of a compound between the barrier layer and the dielectric layer. The compound layer prevents oxidation of the barrier layer and the liner layer due to the oxide present in the dielectric layer and adheres the barrier layer to the dielectric layer.