A method of controlling chemical concentration in electrolyte includes measuring a chemical concentration in an electrolyte, wherein the electrolyte is contained in a tank; and increasing a vapor flux through an exhaust pipe connected to the tank when the measured chemical concentration is lower than a control lower limit value.

Disclosed is a method for producing a wafer map. More specifically, the present invention relates to: a method for producing a wafer map used for manufacturing chips in the semiconductor field, wherein a geographic information system (GIS) technique is used to produce the wafer map; and a method and system for providing wafer test results using same. According to an embodiment of the present invention, a semiconductor wafer is formed as a map by using the GIS technique, a coordinate system used in the GIS is utilized to create a map of the same size as an actual semiconductor wafer, and each of various constituent elements constituting the wafer can be stratified to reflect the actual size of the element to create a wafer map in which each of the elements is geocoded.

The present disclosure is a substrate processing apparatus including: a chamber configured to accommodate a substrate; a heat source configured to heat-treat the substrate; a heat ray sensor provided outside the chamber and configured to receive infrared rays radiated from the substrate; and an infrared ray transmission window provided in the chamber and configured to transmit an infrared ray having a wavelength greater than or equal to 8 μm to the heat ray sensor.

The present invention is an IC chip mounting apparatus for mounting an IC chip at a reference position of an inlay antenna while conveying the antenna, the IC chip mounting apparatus including: a nozzle configured to suck an IC chip when located at a first position and to place the IC chip at the reference position of the antenna when located at a second position; a nozzle attachment to which the nozzle is attached; an image acquisition unit configured to acquire an image of the IC chip sucked by the nozzle; and a correction amount determination unit configured to determine correction amounts for the IC chip sucked by the nozzle, based on the image acquired by the image acquisition unit. The correction amounts includes a first correction amount for correcting an angle of the nozzle around the axis, a second correction amount for correcting a position of the antenna in a conveying direction of the antenna, and a third correction amount for correcting the position of the antenna in a width direction.

The present application discloses an acceptability check method and check system for detection tools. The check method includes: detecting a plurality of wafers using a detection tool to be checked, to obtain first detection data; detecting the plurality of wafers using an existing detection tool, to obtain second detection data; performing data analysis on the first detection data and the second detection data to obtain category classifications corresponding to the first detection data and the second detection data; and determining whether the first detection data corresponding to the category classification is acceptable; wherein the number of wafers detected using the detection tool to be checked and the number of wafers detected using the existing detection tool are the same.

An apparatus for chemical mechanical polishing of a wafer includes a process chamber and a rotatable platen disposed inside the process chamber. A polishing pad is disposed on the platen and a wafer carrier is disposed on the platen. A slurry supply port is configured to supply slurry on the platen. A process controller is configured to control operation of the apparatus. A set of microphones is disposed inside the process chamber. The set of microphones is arranged to detect sound in the process chamber during operation of the apparatus and transmit an electrical signal corresponding to the detected sound. A signal processor is configured to receive the electrical signal from the set of microphones, process the electrical signal to enable detection of an event during operation of the apparatus, and in response to detecting the event, transmit a feedback signal to the process controller. The process controller is further configured to receive the feedback signal and initiate an action based on the received feedback signal.

A substrate processing system includes a process chamber, one or more robot, a substrate measurement system, and a computing device. The process chamber may process a substrate that will comprise a film and/or feature after the processing. The one or more robot, to move the substrate from the process chamber to a substrate measurement system. The substrate measurement system may measure the film and/or feature on the substrate and generate a profile map of the film and/or feature. The computing device may process data from the profile map using a first trained machine learning model, wherein the first trained machine learning model outputs a first chamber component condition estimation for a first chamber component of the process chamber. The computing device may then determine whether to perform maintenance on the first chamber component of the process chamber based at least in part on the first chamber component condition estimation.

A method of detecting a polishing endpoint includes storing a plurality of library spectra, measuring a sequence of spectra from the substrate in-situ during polishing, and for each measured spectrum of the sequence of spectra, finding a best matching library spectrum from the plurality of library spectra to generate a sequence of best matching library spectra. Each library spectrum has a stored associated value representing a degree of progress through a polishing process, and the stored associated value for the best matching library spectrum is determined for each best matching library spectrum to generate a sequence of values representing a progression of polishing of the substrate. The sequence of values is compared to a target value, and a polishing endpoint is triggered when the sequence of values reaches the target value.

To provide a wavelength selection method or a plasma processing method to achieve accurate detection of residual thickness or etching amount, there is provided a plasma processing method, in which a processing object wafer is disposed within a processing chamber in the inside of a vacuum container, and plasma is generated by supplying a processing gas into the processing chamber and used to process a processing-object film layer beforehand formed on a surface of the wafer, and at least two wavelengths are selected from among wavelengths with large mutual information in emission of a plurality of wavelengths of plasma generated during processing of the processing-object film layer, and a temporal change in the emission of at least the two wavelengths is detected, and an endpoint of the processing of the film layer is determined based on a result of the detection.

A white light illumination source can illuminate a region of a substrate to be plasma etched with an incident light beam. A camera takes successive images of the region being illuminated during a plasma etch process. Image processing techniques can be applied to the images so as to identify a location of at least one feature on the substrate and to measure a reflectivity signal at the location. The plasma etch process can be modified in response to the measured reflectivity signal at the location.