A disclosed plasma processing system 10 includes: a plasma processing apparatus 100 including a processing chamber 100a for plasma processing an object 400 to be processed, and at least one component 122, 131 which is at least partially disposed in the processing chamber 100a; a storage unit 301 for storing a recipe including a set value specifying a plasma processing condition; a tolerance determination unit 302 that determines a tolerance of the set value, based on a degree of deterioration of the at least one component 122, 131; and a recipe modification unit 303 that modifies the recipe such that the set value falls within the tolerance, when the set value is outside the tolerance.

A system and method for monitoring a semiconductor process includes a plurality of sensors and a microcontroller. The plurality of sensors are disposed within a process chamber. The microcontroller receives data from the plurality of sensors and measures the uniformity of a semiconductor process based on the data received from the plurality of sensors.

Disclosed is an apparatus for treating a substrate. The substrate treating apparatus may include a chamber for generating plasma in a treating space and treating a substrate using the plasma, and a measurement unit for monitoring light emitted from the plasma of the treating space, in which the measurement unit may include a light collection unit for collecting the light passing through a view port formed on one side wall of the chamber; and an optical cable having a connection terminal fastened to the light collection unit formed at one end to transmit the light, in which a measurement member capable of measuring a fastening length between the light collection unit and the optical cable is disposed in the connection terminal.

A method is provided for in-situ monitoring of etch uniformity during plasma etching, on the basis of the detection of interferometry patterns. The method is applicable to a reactor wherein a plasma is created in the area between the surface to be etched and a counter-surface arranged essentially parallel to the surface to be etched. The occurrence of interference patterns is detected at a location that is placed laterally with respect to the area between the surface to be etched and the counter-surface. The presence of an interference pattern at a particular wavelength is observed through the detection of oscillations of the light intensity measured by an optical detector, preferably by the standard Optical Emission Spectrometry tool of the reactor. When these oscillations are no longer detectable, non-uniformity exceeds a pre-defined limit. The counter surface is arranged such that the oscillations are detected.

A method of fabricating a semiconductor device includes etching a stack of first-material layers and second-material layers alternately disposed one on another on a substrate. An upper portion of the stack is etched using an end point detection (EPD) signal of an etching reaction gas, and a function of an injection time of an etchant with respect to a depth of an opening is obtained while the upper portion of the stack is etched. A lower portion of the stack is etched using the obtained function.

There is provided a gas analyzer apparatus including: a sample chamber which is equipped with a dielectric wall structure and into which only sample gas to be measured is introduced; a plasma generation mechanism that generates plasma inside the sample chamber, which has been depressurized, using an electric field and/or a magnetic field applied through the dielectric wall structure; and an analyzer unit that analyzes the sample gas via the generated plasma. By doing so, it is possible to provide a gas analyzer apparatus capable of accurately analyzing sample gases, even those including corrosive gas, over a long period of time.

A method of cleaning a chamber of a plasma processing device with radicals includes creating a plasma within a remote plasma source which is separated from the chamber, the plasma including radicals and ions, cleaning the chamber by allowing radicals to enter the chamber from the remote plasma source while preventing the majority of the ions created in the remote plasma source from entering the chamber, detecting a DC bias developed on a component of the chamber during cleaning; and using the detected DC bias to determine an end-point of the cleaning and, on determination of the end-point, to stop the cleaning.

Plasma processing conditions may be changed for localized regions of a substrate. A reactive gas may be maintained in a localized region of a substrate while other regions of the substrate are not exposed to the reactive gas. Thus, plasma conditions may be generated at specific regions of the substrate. A multi-zoned gas injection system may be utilized to direct certain gases in certain regions of the plasma space. Techniques may be provided to maintain these gases in the desired regions, as opposed to the gases spreading across the substrate surface. Reactive gases may be provided in one region while a flow of inert gas is provided in other regions in which it is desired to restrict the effects of the reactive gases. Localized control of the plasma process may be provided as a separate plasma processing step. The localized region of the substrate may be the substrate edge.

A method, device, server and computer-readable storage medium for monitoring particles in an etching chamber are provided. When performing a WAC process in the etching machine, an EPD data curve of spectral signal intensity varying with time in the etching machine can be obtained through an OES EPD module, the EPD data differential curve can be obtained through differentiation calculation performed on the EPD data curve, and a particle-drop determination can be performed on the etching chamber by acquiring and analyzing the peak value signal of the EPD data differential curve. The OES EPD module directly monitors particle dropping during the WAC process in the etching chamber, so as to facilitate subsequent processes. The present disclosure reduces labor cost, improves determination accuracy, and avoids contamination of the etching chamber and process wafers caused by particle droppings, thereby improving monitoring efficiency, reducing losses, and reducing negative impact on wafer quality.

An etching method of etching apparatus is disclosed. The etching apparatus performs an etching process on a material to be processed which includes a material layer and a mask layer formed on the material layer. The etching method includes the following steps. The mask layer is etched. A light intensity at a specific wavelength for light generated is detected when the etching process is performed on the mask layer to be processed and an end point detection signal is generated. An etching completion time of the mask layer to be etched is determined according to the end point detection signal. A thickness of the mask layer to be etched is calculated according to the etching completion time. An etching time of the material layer is adjusted according to the thickness of the mask layer to be etched. The material layer is etched after adjusting the etching time.