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 for detecting radicals in process gases in a semiconductor fabrication assembly is provided where the semiconductor fabrication includes a plasma source and a mass spectrometer with an ion source. The method includes separating ions from the process gases and determining a fixed electron energy in which to measure the process gases. Process gases in the semiconductor fabrication assembly are continuously sampled. A first measurement is performed on the sampled process gases at the electron energy using the mass spectrometer, where the first measurement is performed with the plasma source off. A second measurement of the sampled process gases is performed at the fixed electron energy using the mass spectrometer, where the second measurement is performed with the plasma source on. An amount of a radical present in the sampled process gases is determined as a difference between the second measurement and the first measurement.

Embodiments of the present disclosure relate to a method and an apparatus for monitoring plasma behavior inside a plasma processing chamber. In one example, a method for monitoring plasma behavior includes acquiring at least one image of a plasma, and determining a plasma parameter based on the at least one image.

Embodiments disclosed herein include a processing tool for measuring neutral radical concentrations. In an embodiment, the processing tool comprises a processing chamber, and a neutral radical mass spectrometry (NRMS) analyzer fluidically coupled to the processing chamber. In an embodiment, the NRMS analyzer comprises a first chamber fluidically coupled to the processing chamber, where the first chamber comprises a modulator, and a second chamber fluidically coupled to the first chamber, where the second chamber is a residual gas analyzer or a mass spectrometer. In an embodiment, an unobstructed line of sight passes from the processing chamber to the second chamber.

Embodiments of the present invention provide apparatus, systems and methods for measuring dissociation of a process gas generated by a RPS. In one embodiment, a method of measuring dissociation of a process gas includes receiving a process gas from a RPS, the process gas including a polyatomic molecule that dissociates into at least one free radical. The method further includes irradiating the process gas with IR radiation at one or more wavelengths, detecting the IR radiation that passes through the process gas, and determining a degree of dissociation of the polyatomic molecule in the process gas based, at least in part, on the detected IR radiation. In one embodiment, the method further comprises modifying one or more settings of the RPS, based, at least in part, on the determined degree of dissociation.

A system and method provides a more precise mole delivery amount of a process gas, for each pulse of a pulse gas delivery, by measuring a concentration of the process gas and controlling the amount of gas mixture delivered in a pulse of gas flow based on the received concentration of the process gas. The control of mole delivery amount for each pulse can be achieved by adjusting flow setpoint, pulse duration, or both.

Embodiments described herein generally related to a substrate processing apparatus, and more specifically to an improved showerhead assembly for a substrate processing apparatus. The showerhead assembly includes a chill plate, a gas plate, and a gas distribution plate having a top surface and a bottom surface. A plurality of protruded features contacts the top surface of the gas distribution plate. A fastener and an energy storage structure is provided on the protruded features. The energy storage structure is compressed by the fastener and axially loads at least one of the protruded features to compress the chill plate, the gas plate and the gas distribution plate.

A substrate processing system includes a substrate processing apparatus and a switching timing creation support device, wherein the switching timing creation support device includes: an acquisition part configured to acquire, for each of a plurality of properties of particles contained in a gas in the substrate processing apparatus during a processing for a substrate, a measured value of an amount of the particles from a measuring device; a selection part configured to select properties of a predetermined number of the particles in descending order of temporal variations in the amount of the particles; a determination part configured to determine an operation expression and a switching condition for determining a switching timing based on a temporal change in the amount of the particles for each of the selected properties of the particles; and an output part configured to output the operation expression and the switching condition to the substrate processing apparatus.

Methods and systems for dry cleaning a semiconductor processing reaction chamber are disclosed herein. In some embodiments, a method for cleaning a semiconductor processing reaction chamber includes: performing a plasma-assisted cleaning process to clean tube deposits formed on an inner surface of the deposition reaction chamber, the plasma-assisted cleaning process comprises: providing a first reactant gas to a remote plasma source chamber to generate a plasma, wherein the plasma comprising a fluorine-containing radical; and providing the plasma from the remote plasma source chamber to the deposition reaction chamber to clean the tube deposits, and performing a chemical cleaning process by providing a second reactant gas to the deposition reaction chamber after performing the plasma dry cleaning process.

A system and method provides a more precise mole delivery amount of a process gas, for each pulse of a pulse gas delivery, by measuring a concentration of the process gas and controlling the amount of gas mixture delivered in a pulse of gas flow based on the received concentration of the process gas. The control of mole delivery amount for each pulse can be achieved by adjusting flow setpoint, pulse duration, or both.