The storage container according to the embodiment of the present invention includes a storage portion storing a liquid composition containing an organic solvent having a moisture concentration of 400 ppm by mass or less and a surface treatment agent. At least a portion, which is in contact with the liquid composition, of an inner wall of the storage portion has a contact angle θ with respect to water of 10 degrees or more and 150 degrees or less.

An EUV cleaner system and process for cleaning a EUV carrier. The euv cleaner system comprises separate dirty and cleaned environments, separate cleaning chambers for different components of the double container carrier, gripper arms for picking and placing different components using a same robot handler, gripper arms for holding different components at different locations, horizontal spin cleaning and drying for outer container, hot water and hot air (70C) cleaning process, vertical nozzles and rasterizing megasonic nozzles for cleaning inner container with hot air nozzles for drying, separate vacuum decontamination chambers for outgassing different components, for example, one for inner and one for outer container with high vacuum (e.g., <10−6 Torr) with purge gas, heaters and RGA sensors inside the vacuum chamber, purge gas assembling station, and purge gas loading and unloading station.

A semiconductor manufacturing apparatus includes a chuck stage, a scrubber nozzle, a scrubber nozzle scan mechanism, a stage rotation mechanism, and a holding stage including a holding fluid nozzle and a top plate, the top plate having one main surface facing an opposite surface of a wafer, and the holding fluid nozzle being disposed adjacent to a center rather than a periphery portion of the top plate. A holding fluid discharged from the holding fluid nozzle is caused to flow through an area between the opposite surface of the wafer and the one main surface of the top plate to produce holding force, and the holding force causes the opposite surface to hold pressure applied to a processing surface of the wafer by a scrubbing fluid discharged from the scrubber nozzle.

Some embodiments include methods of removing particles from over surfaces of semiconductor substrates. Liquid may be flowed across the surfaces and the particles. While the liquid is flowing, electrophoresis and/or electroosmosis may be utilized to enhance transport of the particles from the surfaces and into the liquid. In some embodiments, temperature, pH and/or ionic strength within the liquid may be altered to assist in the removal of the particles from over the surfaces of the substrates.

In parallel with a substrate heating step, a liquid surface sensor is used to monitor the raising of an IPA liquid film. An organic solvent removing step is started in response to the raising of the IPA liquid film over the upper surface of the substrate. At the end of the organic solvent removing step, a visual sensor is used to determine whether or not IPA droplets remain on the upper surface of the substrate.

An embodiment of the present invention provides a substrate cleaning method including: supplying of a liquid cleaning solution containing a thermoreactive polymer resin in a solvent to a substrate; trapping of particles by gelling the liquid cleaning solution by phase transition through first heat treatment; liquefying of the gel-state cleaning solution with the particle trapped therein by phase transition through second heat treatment; and removing of the liquefied cleaning solution by supplying a rinse solution.

Embodiments described herein generally relate to a processing chamber having a reduced volume for performing supercritical drying processes or other phase transition processes. The chamber includes a substrate support moveably disposed on a first track and a door moveably disposed on a second track. The substrate support and door may be configured to move independently of one another and the chamber may be configured to minimize vertical movement of the substrate within the chamber.

An apparatus for cleaning a substrate has a holding unit 60 that holds a substrate W; a rotated unit 30 connected to the holding unit 60; a rotating unit 35 that is provided on a peripheral outer side of the rotated unit 30 and rotates the rotated unit 30; and a cleaning unit 10, 20 that physically cleans the substrate W held by the holding unit 60.

A method for cleaning a substrate includes setting a substrate inside a cleaning chamber, supplying on a surface of the substrate a treatment solution which includes a volatile component and forms a treatment film, vaporizing the volatile component of the treatment solution supplied on the surface of the substrate such that the treatment solution solidifies or is cured on the surface of the substrate and the treatment film is formed on the surface of the substrate, and supplying onto the treatment film formed on the surface of the substrate a removal solution which removes the treatment film.

The purpose of the present invention is to provide a cleaning liquid composition useful in cleaning substrates, etc., which have undergone treatment such as chemical mechanical polishing (CMP) in a process for manufacturing electronic devices such as semiconductor elements. This cleaning liquid composition for cleaning substrates having Cu wiring includes one or more basic compounds and one or more heteromonocyclic aromatic compounds containing a nitrogen atom, and has a hydrogen ion concentration (pH) of 8-11.