An atmosphere-to-vacuum (ATV) transfer module for a substrate processing tool includes a first side configured to interface with at least one loading station, a transfer robot assembly arranged within the ATV transfer module, and a second side opposite the first side. The transfer robot assembly is configured to transfer substrates between the at least one loading station and at least one load lock arranged between the ATV transfer module and a vacuum transfer module (VTM). The second side is configured to interface with the at least one load lock. The transfer robot assembly is arranged adjacent to the second side, and the at least one load lock extends through the second side into an interior volume of the ATV transfer module.

A substrate treating apparatus includes a carrier platform, a transport mechanism, and a controller. The carrier platform places a carrier thereon. The carrier includes a plurality of shelves arranged in an up-down direction. The shelves are each configured to place one substrate thereon in a horizontal posture. The transport mechanism is configured to transport a substrate to a carrier placed on the carrier platform. The controller controls the transport mechanism. The transport mechanism includes a hand and a hand driving unit. The hand supports a substrate. The hand driving unit moves the hand. The controller changes a height position of the hand when the hand is inserted between two of the shelves adjacent to each other in the up-down direction, depending on a shape of a substrate taken from or placed on one of the shelves by the transport mechanism.

A substrate processing apparatus includes a holding unit which holds a substrate horizontally, a facing member which faces an upper surface of the substrate from above and can be engaged with the holding unit, a supporting member which supports the facing member, a raising/lowering unit in which the supporting member is raised and lowered between an upper position at which the supporting member supports the facing member in a state where the facing member is separated above from the holding unit and an engaging position which is a position below from the upper position and at which the holding unit is engaged with the facing member, and a detecting unit which is disposed at the supporting member. The detecting unit detects a position of a portion to be detected which is disposed at the facing member in relation to the detecting unit.

A method of processing a wafer includes preparing a ring-shaped frame having an opening for accommodating a wafer therein, preparing a wafer having a protrusive ring-shaped stiffener on a reverse side thereof in an outer circumferential excess region thereof, producing a frame unit by affixing a tape to the frame and the reverse side of the wafer, capturing an image of the ring-shaped stiffener and setting a center of an inner circumferential circle of the ring-shaped stiffener on the basis of the captured image, rotating the frame unit around the center of the inner circumferential circle of the ring-shaped stiffener to cut the wafer along the inner circumferential circle of the ring-shaped stiffener, and removing the ring-shaped stiffener severed from the frame unit.

There is provided a technique that include: a process chamber configured to process a substrate at which at least one target film and a heat assist film are formed; and an electromagnetic wave generator configured to supply an electromagnetic wave into the process chamber, wherein when the substrate is irradiated with the electromagnetic wave, the heat assist film generates heat and the at least one target film is modified by the heat.

Provided are a waveform analysis method and a waveform analysis device capable of preventing, in advance, a breakage accident during operation and preventing stoppage due to breakdown of machinery and performing efficient maintenance work by specifying a degraded part from among the parts that constitute the machinery. A waveform analysis device 30 is provided with; a signal analysis unit 31 for performing fast Fourier transform for a signal transmitted from a sensor 28 that detects a physical phenomenon in the machinery an impulse extraction unit 32 for extracting an impulse component from spectrum data generated by the signal analysis unit 31; a display unit 35 for displaying waveform data including the impulse component extracted by the impulse extraction unit 32; and a data editing unit 33 for editing, from data of a waveform including the impulse component displayed by the display unit 35, waveform data in a range selected via an input unit 36 by a worker, generating a graph displaying a frequency, a time, and the intensity of the impulse component, and displaying the graph on the display unit 35.

A circulating EFEM includes an introduction port for introducing a gas, a housing for circulating the introduced gas, and a discharge port for discharging the gas from the housing into a discharge pipe. The discharge port includes a box and a damper. The box is disposed to surround a discharge opening formed on the housing and connected to the discharge pipe. The damper is disposed inside the box to close and open the discharge port and adjusts a discharge amount of the gas via the discharge opening by at least partially moving in response to a differential pressure between the housing and the box.

A vertical batch furnace assembly for processing wafers having a cassette handling space, a wafer handling space, and a first wall and separating the cassette handling space from the wafer handling space. The first wall has at least one wafer transfer opening in front of which, at a side of the first wall which is directed to the cassette handling space, a wafer transfer position for a wafer cassette is provided. The cassette handling space comprises a cassette storage having a plurality of cassette storage positions and a cassette handler configured to transfer wafer cassettes between the cassette storage positions and the wafer transfer position. The cassette handler has a first cassette handler arm and a second cassette handler arm.

Electronic device processing systems including an equipment front end module with at least one side storage pod are described. The side storage pod has a chamber including 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. Methods and systems in accordance with these and other embodiments are also disclosed.

A substrate container system comprises a container body having a bottom face, a front opening that enables passage of a substrate, and a back opening opposing the front opening, the back opening having a width smaller than that of the front opening; and a back cover that covers the back opening and establishes sealing engagement with the container body, wherein the back cover comprises a first gas inlet structure that bendingly extends under the bottom face of the container body upon assembly; wherein the first gas inlet structure comprises a downward facing gas intake port opposing the bottom face of the container body.