A method for processing semiconductor wafer is provided. The method includes loading a semiconductor wafer on a top surface of a wafer chuck. The method also includes supplying a gaseous material between the semiconductor wafer and the top surface of the wafer chuck through a first gas inlet port and a second gas inlet port located underneath a fan-shaped sector of the top surface. The method further includes supplying a fluid medium to a fluid inlet port of the wafer chuck and guiding the fluid medium from the fluid inlet port to flow through a number of arc-shaped channels located underneath the fan-shaped sector of the top surface. In addition, the method includes supplying a plasma gas over the semiconductor wafer.

A substrate processing apparatus includes a rotary table configured to hold and rotate a substrate; an electronic component provided at the rotary table and configured to be rotated along with the rotary table; a first electrode unit provided at the rotary table and configured to be rotated along with the rotary table, the first electrode unit comprising multiple first electrodes electrically connected to the electronic component via multiple first conductive lines; an electric device configured to perform a power supply to the electronic component and a transmission/reception of signals; a second electrode unit comprising multiple second electrodes electrically connected to the electric device via multiple second conductive lines and arranged at positions respectively corresponding to the multiple first electrodes to be brought into contact with the multiple first electrodes; and an electrode moving device configured to connect/disconnect the first electrode unit to/from the second electrode unit.

Disclosed in the present disclosure are a cleaning machine and a cleaning method. The cleaning machine includes: a wet cleaning module, configured to execute a wet cleaning process on a wafer; a dry cleaning module, configured to execute a dry cleaning process on the wafer; a conveying module, configured to input the wafer into the wet cleaning module or the dry cleaning module, or output the wafer from the wet cleaning module or the dry cleaning module; a transferring module, configured to transfer the wafer from the wet cleaning module to the dry cleaning module or transfer the wafer from the dry cleaning module to the wet cleaning module; and a processing module, configured to extract gas from the transferring module.

A substrate cleaning method includes: supplying a gas mixture of a cluster forming gas for forming a cluster by adiabatic expansion and a carrier gas having a smaller molecular weight or atomic weight than the cluster forming gas to a nozzle; forming the cluster by injecting the gas mixture from the nozzle; removing particles adhering to the substrate by the cluster; and continuously supplying the carrier gas to the nozzle for a set time period from an end time of the supply of the cluster forming gas to the nozzle.

A cleaning apparatus, method, and dry chamber are provided for cleaning a wafer carrier that holds wafers as part of a semiconductor fabrication process. The cleaning apparatus includes a wet chamber that receives the wafer carrier to be washed and a reservoir in fluid communication with the wet chamber. The reservoir stores a cleaning liquid that is introduced to the wafer carrier within the wet chamber during a washing operation, and a dry chamber is spaced apart from the wet chamber. The dry chamber receives the wafer carrier after the wafer carrier is washed in the wet chamber and holds the wafer carrier during a drying operation. A transport system transports the wafer carrier between the wet chamber and the dry chamber during a cleaning process.

An apparatus includes a measurement chamber configured to retain one or more sample substances. The apparatus includes an entrance window mounted on a side of the measurement chamber. The apparatus includes a light source configured to generate an incident light beam. The apparatus includes a Raman sensor configured to collect inelastically scattered light from the chamber, and measure an intensity of a Raman peak of a first substance from the one or more sample substances based on the collected inelastically scattered light. The apparatus further includes a processor configured to (i) calculate a concentration of the first substance based on at least the measured intensity of the Raman peak of the first substance, (ii) determine the end point of a wafer cleaning process based on a calculated concentration of the first substance, and (iii) terminate the wafer cleaning process based on the determined end point.

A substrate support assembly suitable for use in a reactor including a common processing and substrate transfer region is disclosed. The substrate support assembly includes a susceptor and one or more lift pins that can be used to lower a substrate onto a surface of the susceptor and raise the substrate from the surface, to allow transfer of the substrate from the processing region, without raising or lowering the susceptor.

The present invention provides a substrate treating apparatus. The substrate treating apparatus includes: a liquid treatment chamber configured to treat a substrate with a liquid; a drying chamber configured to dry the liquid-treated substrate; a transfer robot configured to transfer the substrate between the liquid treatment chamber and the drying chamber, and including a hand which is movable along an X-axis, a Y-axis, and a Z-axis and is rotatably driven based on the Z-axis, and on which the substrate is placed; an optical system configured to photograph a form of a liquid film of the substrate, in which when the substrate is transferred from the liquid treatment chamber to the drying chamber, the substrate is wetted with a chemical liquid and is transferred by the transfer robot in a state of being formed with a liquid film formed; and a controller configured to measure the form of the liquid film photographed by the optical system.

A low surface tension liquid supply unit supplies a low surface tension liquid onto the upper surface of a substrate to form a liquid film of the low surface tension liquid on the substrate. An opening is formed in a central region of the liquid film of an organic solvent. The liquid film is removed from the upper surface of the substrate by expanding the opening. While a low surface tension liquid is supplied from the low surface tension liquid supply unit, to the liquid film, toward a liquid landing point set outside the opening, the liquid landing point is moved so as to follow the expansion of the opening. While an facing surface of a drying head faces a dry region set inside the opening to form a low-humidity space between the facing surface and the dry region, with the low-humidity space having a humidity lower than that outside the space, the dry region and the facing surface are moved so as to follow the expansion of the opening.

A cleaning method includes: supplying a cleaning gas in a processing container while continuously increasing a pressure in the processing container in a stepwise manner at a plurality of time points, thereby executing a cleaning of the processing container by removing a film deposited in the processing container; and detecting an end point of the cleaning based on time-dependent data of a concentration of a predetermined gas generated during the executing the cleaning, for each pressure of the plurality of time points. The executing the cleaning is implemented when the time-dependent data of the concentration of the predetermined gas generated in the continuously increasing the pressure changes from an increasing state to a decreasing state after exceeding a threshold value.