The present disclosure provides a method and system for controlling a deposition device, relating to the field of semiconductor technology. The method for controlling a deposition device is applied to the deposition device, the deposition device includes a reaction chamber and an electrostatic chuck arranged in the reaction chamber, the electrostatic chuck carries a wafer, and the controlling method includes: obtaining a pressure value between the wafer and the electrostatic chuck; and when the pressure value exceeds a preset range, the deposition device sending out an alarm signal, and executing a cleaning operation according to a use state of the electrostatic chuck.

A method includes forming an inner chamber in a process chamber of a plasma processing apparatus, the inner chamber having smaller volume than the process chamber. At least one gas is introduced into the inner chamber, and flow of the at least one gas into the inner chamber is measured. The flow of the at least one gas is adjusted to a desired rate, and a wafer is processed by the at least one gas at the desired rate while the inner chamber is not formed.

A plasma processing apparatus which forms a first film on a pattern formed on a substrate having dense and coarse areas, and then performs sputtering or etching on the first film.

There is provided a learning method. The method includes performing preprocessing on light emission data in a chamber of a plasma processing apparatus, setting a constraint for generating a regression equation representing a relationship between an etching rate of the plasma processing apparatus and the light emission data, selecting a learning target wavelength from the light emission data subjected to the preprocessing, and receiving selection of other sensor data different from the light emission data. The method further includes generating a regression equation based on the set constraint while using, as learning data, the selected wavelength, the received other sensor data, and the etching rate, and outputting the generated regression equation.

A system for plasma ignition and maintenance of an atmospheric pressure plasma. The system has a variable frequency alternating current (AC) power source, a transformer, a cable connected to a secondary winding of the transformer, a programmed microprocessor for control of power to the atmospheric pressure plasma. The microprocessor is configured to a) at pre-ignition, power the AC power source at an operational frequency f.sub.op higher than the resonant frequency f.sub.r, b) decrease the operational frequency f.sub.op of the AC power source until there is plasma ignition, and c) after the plasma ignition, further decrease the operational frequency f.sub.op of the AC power source to a frequency lower than the resonant frequency f.sub.r.

A method for achieving uniformity in an etch rate is described. The method includes receiving a voltage signal from an output of a match, and determining a positive crossing and a negative crossing of the voltage signal for each cycle of the voltage signal. The negative crossing of each cycle is consecutive to the positive crossing of the cycle. The method further includes dividing a time interval of each cycle of the voltage signal into a plurality of bins. For one or more of the plurality of bins associated with the positive crossing and one or more of the plurality of bins associated with the negative crossing, the method includes adjusting a frequency of a radio frequency generator to achieve the uniformity in the etch rate.

Embodiments of the present technology may include semiconductor processing methods that include depositing a film of semiconductor material on a substrate in a substrate processing chamber. The deposited film may be sampled for defects at greater than or about two non-contiguous regions of the substrate with scanning electron microscopy. The defects that are detected and characterized may include those of a size less than or about 10 nm. The methods may further include calculating a total number of defects in the deposited film based on the sampling for defects in the greater than or about two non-contiguous regions of the substrate. At least one deposition parameter may be adjusted as a result of the calculation. The adjustment to the at least one deposition parameter may reduce the total number of defects in a deposition of the film of semiconductor material.

A method of evaluating tool health of a plasma tool is provided. The method includes providing a virtual metrology (VM) model that predicts a wafer characteristic based on parameters measured by module sensors and in-situ sensors of the plasma tool. A classification model is provided that identifies a plurality of failure modes of the plasma tool. An initial test is performed on an incoming wafer to determine whether the incoming wafer meets a preset requirement. The wafer characteristic is predicted using the VM model when the incoming wafer meets the preset requirement. A current failure mode is identified using the classification model when the wafer characteristic predicted by using the VM model is outside a pre-determined range.

A process of detecting a thickness of a film layer to be processed or a depth of etching by using a result of detection of a signal indicating intensity of interference light having a plurality of wavelengths formed at a plurality of time instants from when plasma is formed to when the etching is completed. A start time instant is detected by using an amount of change in the intensity of the interference light. Then, a remaining film thickness or the etching amount at an arbitrary time instant is detected from a result of comparing actual data indicating the intensity of the interference light at the arbitrary time instant during the processing after the start time instant with a plurality of pieces of data for detection of the intensity of the interference light obtained in advance and associated with values of a the film thicknesses or the depths of etching.

A method for achieving a first uniformity level in a processing rate across a surface of a substrate is described. The method includes receiving the first uniformity level to be achieved across the surface of the substrate and identifying a first plurality of duty cycles associated with a first plurality of states based on the first uniformity level. The first plurality of states are of a variable of a first radio frequency (RF) signal. The method further includes controlling an RF generator to generate the first RF signal having the first plurality of duty cycles.