A semiconductor manufacturing apparatus includes a process chamber. A chuck is disposed in the process chamber. The chuck is configured to hold a substrate thereon. A transfer unit is adjacent to the process chamber. The transfer unit includes a transfer hand configured to transfer the substrate. A slow discharge layer is disposed on a first surface of the transfer hand. The slow discharge layer is configured to discharge static electricity charged in the substrate.

According to one aspect of a technique of the present disclosure, there is provided a substrate processing apparatus includes: a substrate support; a process chamber; an upstream side gas guide including: a housing connected to a side portion of the process chamber and extending in a direction away from the process chamber; and partition plates arranged in a vertical direction in the housing; a distributor provided with ejection holes arranged in the vertical direction such that a gas is capable of being supplied through the ejection holes between adjacent partition plates, between the housing and an uppermost partition plate or between the housing and a lowermost partition plate; and a process chamber heater provided between the process chamber and the distributor such that a part thereof is located near an adjacent portion of the housing.

A jig for teaching substrate handling in a semiconductor processing system includes a verification pin with a pin width and a disc body. The disc body has a first surface, a second surface opposite the first surface, and a thickness separating the second surface from the first surface of the disc body. The first and second surfaces define a verification aperture coupling the first surface to the second surface of the disc body. The verification aperture has an aperture width equivalent to the pin width of the verification pin to teach a transfer position by slidably receiving the verification pin in the verification aperture and a verification pin seat defined in a load lock of the semiconductor processing system while supported by a substrate transfer robot within the semiconductor processing system. Semiconductor processing systems and methods of teaching substrate handling in semiconductor processing systems are also described.

The inventive concept provides a sensor station. The sensor station includes a body providing an inner space for storing a substrate-type sensor; a power source unit installed at the body and configured to transmit a power to the substrate-type sensor; a processing unit installed at the body and configured to process a data measured by the substrate-type sensor; and a communication unit installed at the body and configured to exchange a data with the substrate-type sensor and a server of a substrate treating system.

A substrate processing system comprises a module to perform an operation associated with processing a semiconductor substrate in the substrate processing system. The module includes a component used with the processing of the semiconductor substrate, and a file stored in the module. The file includes information about the component of the module. The substrate processing system comprises a controller to communicate with the module via a network of the substrate processing system. The controller receives the file from the module via the network, reads the information about the component from the received file, and maps, based on the information read from the received file, the component of the module to an option in an application used to configure the module. The controller automatically configures the component of the module using the option in the application to which the component of the module is mapped.

A liquid chemical processing device that reduces variation in resist removal for each substrate includes: a processing tank (10a) in which resist removal processing is performed by immersing substrates (4) in a chemical (6); a plurality of holders (22) configured to hold the substrates (4) in a vertical posture; vertical drivers (20) configured to individually and vertically drive the holders (22); and a chuck (55) configured to disengageably chuck the substrates (4), wherein the vertical drivers (20) are configured to individually and vertically move the holders (22) between an immersed position where the substrates (4) are immersed in the chemical (6) and a non-immersed position where the substrates (4) are lifted up from the chemical (6), and the substrates (4) held by the holders (22) are subjected to the resist removal processing in a single wafer manner.

An adjustable joint for insertion into a linkage of a substrate handler utilized for substrate processing. The adjustable joint allows for adjusting the pitch and roll of an attached link. Such adjustment may permit aligning a pickup surface of an end effector to a desired plane. Once adjusted, the joint may be fixed to maintain the desired orientation of the attached link. The adjustable joint allows for correcting deflection of a pickup surface of an end effector relative to a desired pickup plane due to, for example, drooping caused by high temperature usage, mechanical tolerances and/or installation errors.

A substrate processing method capable of suppressing corrosion of a conductive material on a surface of a substrate by supplying a liquid having a reduced concentration of dissolved oxygen onto the substrate. The substrate processing method includes: dissolving an inert gas in a liquid at not less than a saturation solubility to replace oxygen dissolved in the liquid with the inert gas; generating bubbles of the inert gas in the liquid by depressurizing the liquid in which the inert gas is dissolved; and processing the substrate while supplying the liquid containing the bubbles to the surface of the substrate.

The present disclosure generally provides for a system and method for measuring one or more characteristics of one or more substrates in a multi-station processing system using one or more metrology modules at a plurality of metrology stations. In one embodiment, a system controller is configured to cause the multi-station processing system to perform a method that includes processing a plurality of substrates at a plurality of processing stations, advancing one or more of the plurality of substrates to a respective metrology station, measuring one or more characteristics of the plurality of substrates at the respective metrology station, determining a processing performance metric based on the one or more characteristics, comparing the processing performance metric to a tolerance limit to determine if an out of tolerance condition has occurred, and adjusting one or more processing parameters when it is determined that an out of tolerance condition has occurred.

Systems and methods for processing workpieces, such as semiconductor workpieces are provided. One example embodiment is directed to a processing system for processing a plurality of workpieces. The processing system can include a loadlock chamber, a transfer chamber, and at least two processing chamber having two or more processing stations. The processing system further includes a storage chamber for storing replaceable parts. The transfer chamber includes a workpiece handling robot. The workpiece handling robot can be configured to transfer a plurality of replaceable parts from the processing stations to the storage chamber.