An apparatus for treating a substrate includes a housing having a treatment space inside, a gas supply unit that supplies a hydrophobic gas into the treatment space to hydrophobicize the substrate, and a support unit that supports the substrate in the treatment space. The support unit includes a support plate, a heating member that heats the substrate placed on the support plate, and a height adjustment member that changes a position of the substrate between a first position spaced apart upward from an upper surface of the support plate by a first distance and a second position spaced apart upward from the upper surface of the support plate by a second distance, and the second position is a higher position than the first position.

A substrate processing apparatus includes: a rotary table provided in a processing container; a rotation mechanism configured to rotate the rotary table; recesses provided on an upper surface of the rotary table along a rotation direction of the rotary table and configured to accommodate substrates, respectively; a processing gas supply provided above the rotary table and configured to supply a processing gas onto the rotary table to process each of the substrates; a heater configured to heat the rotary table; a support configured to support the substrates in upper regions above the recesses so that the heater heats the substrates before being accommodated in the recesses; and an elevating mechanism configured to raise and lower the support relative to the rotary table so that the substrates are collectively moved from the upper regions into the recesses.

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 system is disclosed for transferring a substance pattern to a substrate. The system comprises a nip defined between a roller and an opposing surface, a web carrying the substance pattern driven to pass the nip with a predetermined velocity, and an endless conveyor for transporting the substrate towards the nip, the substrate passing through the nip at the same time, and with the same speed, as the web in order for the substance pattern to be transferred from the web to the substrate. Upon gripping of the substrate by the nip, no further force is applied by the transport conveyor, thereby avoiding compression of the substrate. The endless transport conveyor can be formed with at least one projection configured to engage a trailing edge of the substrate and can be driven to push the substrate towards the nip with a velocity less than the velocity of the web.

A preprocess is efficiently performed on a substrate. A pre-wet module 200 includes a deaeration tank 210, a processing device 258, a substrate holder 220, and a drive mechanism 230. The deaeration tank 210 is configured to house a deaerated liquid. The processing device 258 includes a nozzle 268 configured to supply a cleaning liquid to a surface to be processed of a substrate having the surface to be processed facing upward. The substrate holder 220 is disposed between the deaeration tank 210 and the processing device 258. The substrate holder 220 includes a first holding member 222 configured to hold a first substrate and a second holding member 224 configured to hold a second substrate. The drive mechanism 230 is configured to rotate and move up and down the substrate holder 220. The drive mechanism 230 includes a rotation mechanism 240 and an elevating mechanism 248. The rotation mechanism 240 is configured to rotate the substrate holder 220 between a first state where a surface to be processed of the first substrate is opposed to a deaerated liquid in the deaeration tank 210 and a second state where a surface to be processed of the second substrate is opposed to the deaerated liquid in the deaeration tank. The elevating mechanism 248 is configured to move up and down the substrate holder 220.

A method and apparatus for processing semiconductor substrates is described herein. The apparatus includes one or more growth monitors disposed within an exhaust system of a deposition chamber. The growth monitors are quartz crystal film thickness monitors and are configured to measure the film thickness grown on the growth monitors while a substrate is being processed within the deposition chamber. The growth monitors are connected to a controller, which adjusts the heating apparatus and gas flow apparatus settings during the processing operations. Measurements from the growth monitors as well as other sensors within the deposition chamber are used to adjust processing chamber models of the deposition chamber as substrates are processed therein.

Disclosed is a container that receives a substrate type sensor. The container includes a body having a reception space, one side of which is opened, a door that selectively opens and closes the reception space, a shelf part that supports the substrate type sensor in the reception space, and a charging module that charges the substrate type sensor supported by the shelf part, and the charging module includes a charging part that moves between a standby location and a charging location that charges the substrate type sensor supported by the shelf part.

A carrier system and method carries an object to an object mounting member provided with an object mounting section. The system includes: a measurement device which obtains information related to a flatness of the object; a carrier member that carries the object; and a controller which controls a driving speed of the carrier member using the information related to the flatness of the object obtained by the measurement device.

A pedestal assembly including a pedestal for supporting a substrate. A central shaft positions the pedestal at a height during operation. A ring is placed along a periphery of the pedestal. A ring adjuster subassembly includes an adjuster flange disposed around a middle section of the central shaft. The subassembly includes a sleeve connected to the adjuster flange and extending from the adjuster flange to an adjuster plate disposed under the pedestal. The subassembly includes ring adjuster pins connected to the adjuster plate and extending vertically from the adjuster plate. Each of the ring adjuster pins being positioned on the adjuster plate at locations adjacent to and outside of a pedestal diameter. The ring adjuster pins contacting an edge undersurface of the ring. The adjuster flange coupled to at least three adjuster actuators for defining an elevation and tilt of the ring relative to a top surface of the pedestal.

Disclosed is a capacitively coupled plasma etching apparatus, wherein an electrically conductive supporting rod where a lower electrode is fixed is connected to driving means, the driving means driving the electrically conductive support rod to move axially; besides, the lower electrode is fixed to the bottom of a chamber body via a retractable sealing part, causing the upper surface of the lower electrode to be hermetically sealed in an accommodation space in the chamber body; an electrical connection part is connected on the chamber body; the radio frequency current in the chamber body returns, via the electrical connection part, to the loop end of a radio frequency matcher. In this way, the lower electrode is fixed on the chamber body via the retractable sealing part, such that when the lower electrode is driven by the driving means to move up/down, the chamber body does not move along with it, and the radio frequency loop in the chamber body is in a steady state, thereby achieving stability of the radio frequency loop while implementing adjustability of the plate distance.