A substrate processing technique including: a module including a gas supplier having an upstream side gas guide and a supply structure, a reaction tube communicating with the gas supplier, and a gas exhauster; a supply pipe connected to the gas supplier, and an exhaust pipe connected to the gas exhauster; a carry chamber adjacent to a plurality of the modules; and a piping arrangement region in which the supply pipe or the exhaust pipe can be arranged, in which the reaction tube is disposed at a position overlapping the carry chamber, when the supply pipe is disposed in the piping arrangement region, the gas exhauster is disposed at a position oblique to the shaft and not overlapping the carry chamber, and when the exhaust pipe is disposed in the piping arrangement area, the gas supplier is disposed at a position oblique to the shaft and not overlapping the carry chamber.

Disclosed is a method for processing a substrate, comprising a liquid processing step of performing liquid processing on the substrate by supplying a processing liquid onto the substrate in a liquid processing chamber, a transfer step of transferring the substrate from the liquid processing chamber to a drying chamber, and a drying step of drying the substrate in the drying chamber. In the drying step, the substrate is dried while an edge region of the substrate other than a central region of the substrate is supported by a support unit, and in the liquid processing step, the liquid processing is performed on the substrate such that a height of the processing liquid remaining on the edge region of the substrate is greater than a height of the processing liquid remaining on the central region of the substrate when the liquid processing is completed in the liquid processing chamber.

The invention relates to an apparatus (200, 200A, 300, 400) for a semiconductor production facility handling an object, the apparatus comprising a core module (100) and at least one functionality module (M . . . ). A core module (100) as well as an operating method for such an apparatus are further aspects of the invention.

Provided is a transport robot and a substrate treating apparatus including the transport robot. The substrate treating apparatus includes a transport chamber having a long shape on one side, and for providing a moving space of a substrate, a load lock chamber connected to the transport chamber to provide an exchange space between the transport chamber and a substrate before a process or a substrate after a process, a process unit connected to the transport chamber to perform a process for a substrate transferred from the transport chamber, a track provided in the transport chamber to provide a moving path of a substrate, and a transport robot capable of moving along the track in a non-contact manner, and entering or exiting the load lock chamber to perform a substrate exchange between the load lock chamber and the transport chamber.

A substrate transfer system includes a load lock module, an atmospheric transfer module having a first sidewall adjacent to the load lock module and a second sidewall remote from the load lock module, the atmospheric transfer module being connected to the load lock module, and a substrate transfer robot disposed in the atmospheric transfer module. The substrate transfer robot includes a base configured to reciprocate along the first sidewall, a substrate transfer arm disposed on the base, and a flow rectifier surrounding the base, the flow rectifier being configured, upon movement of the base, to create an obliquely downward air flow in a direction opposite to a moving direction of the base.

A substrate transfer mechanism for transferring a substrate to each of a plurality of stacked processing modules that process the substrate includes an arm base provided with a first driver, a lift configured to move up and down the arm base, a first arm extending transversely from a lower side of the arm base, and having a tip end that pivots around a vertical axis with respect to the arm base by the first driver, a second arm extending transversely from an upper side of the tip end of the first arm, and having a tip end that pivots around a vertical axis with respect to the first arm along with the pivoting of the first arm, and a substrate holder provided on an upper side of the tip end of the second arm, and configured to rotate around a vertical axis with respect to the second arm.

A method of patterning a substrate. The method may include providing a cavity in a layer, disposed on the substrate, the cavity having a first length along a first direction and a first width along a second direction, perpendicular to the first direction, and wherein the layer has a first height along a third direction, perpendicular to the first direction and the second direction. The method may include depositing a sacrificial layer over the cavity in a first deposition procedure; and directing angled ions to the cavity in a first exposure, wherein the cavity is etched, and wherein after the first exposure, the cavity has a second length along the first direction, greater than the first length, and wherein the cavity has a second width along the second direction, no greater than the first width.

Disclosed is an apparatus for transferring a substrate. The apparatus includes a transfer robot, a linear rail unit including a movable plate on which the transfer robot is mounted and a running shaft on which the movable plate travels, and a particle diffusion prevention member that prevents diffusion of particles to the outside by maintaining a differential pressure between the movable plate and the running shaft.

A substrate processing apparatus includes: a vacuum transfer chamber including a substrate transfer mechanism provided in a vacuum transfer space thereof to collectively hold and transfer substrates with a substrate holder; and a processing chamber having processing spaces and connected to the vacuum transfer chamber. The processing chamber includes a loading/unloading port provided on a side of the vacuum transfer chamber to allow the vacuum transfer space and the processing spaces to communicate with each other. The processing spaces include a first processing space in which a first process is performed on the substrate and a second processing space in which a second process is performed on the substrate subjected to the first process. The first and second processing spaces are arranged in a direction in which the substrate is loaded and unloaded, and the substrate holder has a length that extends over the first and second processing spaces.

Embodiments disclosed herein generally relate to a system and, more specifically, a substrate processing system. The substrate processing system includes one or more cooling systems. The cooling systems are configured to lower and/or control the temperature of a body of the substrate processing system. The cooling systems include features to cool the body disposed in the substrate processing system using gas and/or liquid cooling systems. The cooling systems disclosed herein can be used when the body is disposed at any height.