A substrate processing device includes a transfer chamber configured to transfer a substrate under an atmospheric atmosphere and a plurality of processing units each including at least one processing chamber for processing the substrate under a vacuum atmosphere and at least one load-lock chamber connected to the processing chamber to switch an inner atmosphere thereof between the atmospheric atmosphere and the vacuum atmosphere. The transfer chamber includes a connection unit configured to connect the transfer chamber and the load-lock chamber such that each of the processing units is detachably attached. The connection unit includes an opening that allows the transfer chamber to communicate with the load-lock chamber, and an opening/closing mechanism configured to open and close the opening portion.

A high-pressure processing system for processing a layer on a substrate includes a first chamber, a support to hold the substrate in the first chamber, a second chamber adjacent the first chamber, a foreline to remove gas from the second chamber, a vacuum processing system configured to lower a pressure within the second chamber to near vacuum, a valve assembly between the first chamber and the second chamber to isolate the pressure within the first chamber from the pressure within the second chamber, a gas delivery system configured to increase the pressure within the first chamber to at least 10 atmospheres while the first chamber is isolated from the second chamber, an exhaust system comprising an exhaust line to remove gas from the first chamber, and a common housing surrounding both the first gas delivery module and the second gas delivery module.

Disclosed herein are systems and methods relating to a transfer chamber for an electronic device processing system. The transfer chamber can include a first magnetic levitation track having a face-up orientation and a second magnetic levitation track spaced from the first magnetic levitation track and having a face-down orientation. The system can include substrate carriers that move along the first and second magnetic levitation tracks where each substrate carrier includes a magnet on a bottom portion to interact with a first magnetic field and a second magnet on a top portion to interact with a second magnetic field. The system also can include at least one lift pin assembly to move the substrate carriers in a vertical direction between the first and second magnetic levitation tracks.

A particle removed from a substrate is suppressed from adhering to the substrate again. A substrate cleaning apparatus includes a substrate holder configured to hold the substrate; a gas nozzle configured to jet a cleaning gas to the substrate on the substrate holder; and a nozzle cover provided to surround the gas nozzle. The cleaning gas is jetted to a decompression chamber of the nozzle cover from the gas nozzle, and a gas cluster configured to remove the particle on the substrate in the decompression chamber is generated. A gas for a gas curtain is jetted from a holder support of the substrate holder toward the nozzle cover, and the gas curtain is formed between the nozzle cover and the holder support.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a chamber providing an inner space; a fluid supply unit configured to supply a drying fluid to the inner space; and a fluid exhaust unit configured to exhaust the drying fluid from the inner space, and wherein the fluid exhaust unit includes an exhaust line connected to the chamber; a pressure adjusting member installed at the exhaust line and configured to maintain a pressure of the inner space at a set pressure; and a heating member installed at the pressure adjusting member or a back end of the pressure adjusting member.

The present invention provides a substrate treating apparatus including: a support unit for supporting and rotating a substrate on which a first pattern and a second pattern different from the first pattern are formed; a liquid supply unit for supplying a treatment liquid to the substrate supported on the support unit; and a heating unit for heating any one of the first pattern and the second pattern.

There is provided a configuration that includes: an intake damper and an intake fan configured to communicate with an intake port that sucks air to a transfer chamber connected to a process chamber; a valve of an inert gas introduction pipe configured to supply an inert gas to the transfer chamber; an exhaust fan and a first exhaust valve installed in the transfer chamber; a switch configured to select one of an atmospheric mode in which an atmosphere of the transfer chamber is an air atmosphere and a purge mode in which the atmosphere of the transfer chamber is an inert gas atmosphere; and a controller configured to control each of the intake damper, the intake fan, the valve of the inert gas introduction pipe, the exhaust fan, and the first exhaust valve to execute one of the atmospheric mode and the purge mode.

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 carrier spacer includes an annular main body, a first tapered part formed on an inner peripheral part of a front surface of the main body, a second tapered part formed on the inner peripheral part of a reverse surface of the main body, a flat surface formed on the outer peripheral side of the first tapered part on the front surface of the main body and holding the reverse surface of the outer peripheral part of a semiconductor wafer, a peripheral edge part formed on the outer peripheral side of the flat surface of the main body and provided with a step having a height position higher than a height position of the flat surface, an arcuate cutout part formed from the peripheral edge part to the flat surface of the main body, and a pair of handles protruding from the peripheral edge part toward the outer peripheral side.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a treating container having a treating space; a support unit configured to support and rotate a substrate in the treating space; an exhaust line coupled to the treating container and configured to exhaust an airflow within the treating space; a support frame provided independently of a rotation of the support unit and positioned between the treating container and the support unit; and a guide vane protruding to an outside of the support frame and configured to guide the airflow within the treating space in a downward direction.