A substrate treating method for treating substrates with a substrate treating apparatus having an indexer section, a treating section and an interface section includes performing resist film forming treatment in parallel on a plurality of stories provided in the treating section and performing developing treatment in parallel on a plurality of stories provided in the treating section.

Pump liners and process chambers with the pump liners are described. The pump liner has a ring-shaped body with an annular wall enclosing a process region. A plurality of circumferentially spaced openings provide fluid communication through the annular wall between the process region and a region outside of the ring-shaped body. Each of the plurality of circumferentially spaced openings has a self-adjusting valve assembly. Self-adjusting valves and processing methods are also described.

The inventive concept provides a method for treating a substrate. In an embodiment, the substrate treating method includes a treatment step of treating a residue on the substrate with a first fluid in a supercritical state and a second fluid in a supercritical state in a process space of a chamber, and the first fluid in the supercritical state and the second fluid in the supercritical state have different densities.

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.

A substrate processing system installed on a floor face is provided. The substrate processing system includes a substrate transfer module, a supporting table including a top plate disposed separately from the floor face, a plurality of substrate processing modules disposed on the top plate and coupled to the substrate transfer module along a lateral side of the substrate transfer module, and a plurality of power units disposed below the top plate. Further, the plurality of power units correspond to the plurality of substrate processing modules, respectively, and each of the power units is configured to supply electric power to the corresponding processing module.

Examples of the present invention provide an apparatus for transferring substrates and confining a processing environment in a chamber. One example provides a hoop assembly for use in a processing chamber. The hoop assembly includes a confinement ring defining a confinement region therein. A hoop body mates with the confinement ring. The hoop body is slanted to reduce a thickness across a diameter of the hoop body. Three or more lifting fingers are attached to the hoop body and extend downwards. Each of the three or more lifting fingers has a contact tip positioned radially inward from the hoop body to form a substrate support surface below and spaced apart from the confinement region.

A substrate treatment method of treating a substrate using a block copolymer containing a hydrophilic polymer and a hydrophobic polymer, includes: a resist pattern formation step of forming a predetermined resist pattern by a resist film on the substrate; a thin film formation step of forming a thin film for suppressing deformation of the resist pattern on a surface of the resist pattern; a block copolymer coating step of applying a block copolymer to the substrate after the formation of the thin film; and a polymer separation step of phase-separating the block copolymer into the hydrophilic polymer and the hydrophobic polymer.

A substrate processing apparatus includes processing parts performing substrate processing on target substrates, respectively, substrate mounting tables mounting the target substrates thereon in the respective processing parts, gas introducing members introducing processing gases into processing spaces, a common exhaust mechanism evacuating the processing spaces at once and further performing pressure control for the processing spaces at once, and a pressure measuring part configured to selectively monitor a pressure in any one of the plurality of processing spaces by using a pressure gauge. The pressure measuring part includes pipelines having pressure-measuring pipelines configured to connect the processing spaces to the pressure gauge and dummy pipelines configured to communicate with the processing spaces, which adjust a difference between a volume of the pipelines communicating with a monitored processing space of the processing spaces and a volume of the pipelines communicating with each of non-monitored processing spaces.

Apparatus, systems, and methods for processing workpieces are provided. In one example implementation, a hydrogen gas mixed with an inert gas can be reacted with an oxygen gas to oxidize a workpiece at atmospheric pressure. A chemical reaction of a hydrogen gas with an oxygen gas facilitated by a hot workpiece surface can positively affect an oxidation process. A reaction speed of the chemical reaction can be slowed down by mixing the hydrogen gas with an inert gas. Such mixture can effectively reduce a partial pressure of the hydrogen gas. As such, the oxidation process can be carried out at atmospheric pressure, thereby, in an atmospheric thermal processing chamber.

A method for arranging a substrate processing tool on a pedestal within a semiconductor fabrication room includes supporting a plurality of pedestal plates on a pedestal frame including a plurality of stanchions. The method further includes determining dimensions of the pedestal plates, determining locations of installation features of the pedestal plates in accordance with components of the substrate processing tool, machining the installation features in the pedestal plates based on the determined locations, marking at least one of the pedestal plates with at least one alignment feature, and installing the pedestal frame on a subfloor of the semiconductor fabrication room. The stanchions of the pedestal frame are positioned such that a weight distribution of the pedestal frame on the subfloor is different from a weight distribution of the substrate processing tool.