A method of diagnosing a load port includes identifying a plurality of entities for a plurality of substrate storage containers by a plurality of load ports capable of transferring a substrate into and out of the plurality of substrate storage containers; detecting directly or indirectly a plurality of states of the plurality of substrate storage containers by a plurality of sensors provided at the plurality of load ports; associating the plurality of load ports, the plurality of entities and a plurality of sensor values, with each other; accumulating, in a database, data associated in the act of associating the plurality of load ports, the plurality of entities, and the plurality of sensor values; and analyzing the data in the database and determining a state of each of the plurality of load ports.

The application discloses a placement system for a door of a wafer pod, including a loadport. A docking interface is formed in the loadport, a placement mechanism is arranged on one side surface of the loadport, and includes a swing component, a follower component, and a docking plate. The swing component and the follower component are respectively connected to the docking plate, and the swing component can drive the docking plate to place the docking plate obliquely above the docking interface. By utilizing the space at the top of the loadport, the structural layout of the loadport is more reasonable; and the docking plate is placed nearly horizontally after the door is placed at a designated position, and provides a supporting force to the door, so that dependence on the vacuum suction is decreased, thereby avoiding the influences due to fluctuations of air pressure.

A load port adapter is a load port adapter fixable on a mounting table of a load port. The load port adapter includes a holder capable of holding a cassette capable of accommodating a plurality of circuit boards. The holder is fixable on the mounting table of the load port. The holder includes a position adjustment mechanism configured to position the cassette at a reference position. In the cassette clamped on the load port adapter, the reference position is a reference position on a load port adapter side when the circuit board is taken out from the cassette.

Systems and methods are described for integrated decomposition and scanning of a semiconducting wafer, where a single chamber is utilized for decomposition and scanning of the wafer of interest.

A substrate processing system includes a hinge assembly configured to allow a substrate support and an RF bias assembly to slide, from a docked position to an undocked position, relative to other components of a processing chamber. A make-break connector is configured to supply fluid to at least one of the substrate support and the RF bias assembly. The make-break connector includes a first portion including a first fluid passage connected to a first conduit. A second portion includes a second fluid passage connected to a second conduit. The first fluid passage in the first portion fluidly communicates with the second fluid passage in the second portion. The first portion is configured to slide with the substrate support and the RF bias assembly relative to the second portion and the other portions of the processing chamber. The first portion is located inwardly relative to the second portion.

A factory interface for an electronic device manufacturing system can include a load lock disposed within the interior volume of a factory interface and a factory interface robot disposed within the interior volume of the factory interface. The factory interface robot can be configured to transfer substrates between a first set of substrate carriers and the first load lock. The factory interface robot can comprise a vertical tower, a plurality of links, and an end effector.

Electronic device processing systems including an equipment front end module (EFEM) with at least one side storage pod are described. The side storage pod has a chamber including a storage container. The storage container includes at least a top substrate holder and a bottom substrate holder. In some embodiments, an exhaust port is located at a midpoint between the top substrate holder and the bottom substrate holder. A gas flow component is configured to provide a gas flow between the EFEM body and the storage container. A gas flow temperature component is configured to modify the temperature of the gas flow to a particular temperature.

Exemplary substrate processing systems may include a chamber body defining a transfer region. The systems may include a first lid plate seated on the chamber body along a first surface of the first lid plate. The first lid plate may define a plurality of apertures through the first lid plate. The systems may include a plurality of lid stacks equal to a number of apertures of the plurality of apertures. The plurality of lid stacks may at least partially define a plurality of processing regions vertically offset from the transfer region. The systems may include a second lid plate coupled with the plurality of lid stacks. The plurality of lid stacks may be positioned between the first lid plate and the second lid plate. A component of each lid stack of the plurality of lid stacks may be coupled with the second lid plate.

The present disclosure relates to systems and methods for reducing the humidity within a FOUP (Front Opening Unified Pod) when loaded on an EFEM (Equipment Front End Module) for transfer of a semiconductor wafer substrate during fabrication processes. A deflector of specified structure is placed inside the EFEM above the load port of the FOUP. The deflector directs airflow in the EFEM away from the load port. The deflector includes a body with a plurality of apertures in the deflector body, and with a sloped front surface. Thus, the degree of penetration of high-humidity air from the EFEM into the FOUP is reduced.

A substrate processing system includes a processing container body having an opening, a lid which closes an opening, a mover for relatively moving the lid with respect to the opening to open and close the opening, and a lock mechanism which locks the lid to the processing container body. The lock mechanism includes an arm member and a locking member. The arm member is provided on one of the processing container body and the lid and extends toward the other when the processing container body is located at a position where the lid is separated from the processing container body. The locking member restricts a displacement of the arm member by being engaged with a part of the arm member. This part is located beyond the gap space when the lid is at the separated position.