A RF detector is provided and includes LO and RF paths, a mixer and a filter. The LO path includes a first buffer and a sine-to-square wave converter. The first buffer receives a first RF signal that is based on a RF input signal received by the RF detector. The RF input signal is detected within a substrate processing system. The sine-to-square wave converter converts a sine wave of the first RF signal to a square wave and outputs a LO signal having the square wave. The RF path includes a second buffer that receives a second RF signal and outputs a RF output signal. The second RF signal is based on the RF input signal. The mixer generates an IF signal based on the LO and RF output signals. The filter filters the IF signal to generate a DC signal, which is representative of the second RF signal.

Provided are a method and a device that can measure sputtered particles discharged by sputtering with high precision within a short time. A measuring device has a measuring section that measures a ratio between an equivalent value of the number of ion particles discharged from a target by sputtering caused by a pulsed electric discharge and an equivalent value of the number of neutral particles discharged from the target by the pulsed electric discharge. The ratio between the number of the ion particles and the number of the neutral particles discharged from the target by the sputtering can be regarded as one of factors affecting quality of a vapor-deposited film, a film growth rate and an etching rate. Thus, a factor affecting the quality of the vapor-deposited film, the film growth rate and the etching rate can be grasped and also controlled.

In an embodiment, a plasma processing tool with an extendable probe is described. In an embodiment, the plasma processing tool comprises a chamber, and a pedestal for supporting a substrate. In an embodiment, an edge ring is around a perimeter of the pedestal. Additionally, a sensor at an end of a probe is provided. In an embodiment, the probe is configured to extend over the pedestal.

A plasma processing apparatus includes: a plasma processing chamber; a radio frequency power source; a sample stage on which a sample is mounted; an electrode which is arranged inside the sample stage and electrostatically chucks the sample; a DC power source which applies a DC voltage to the electrode; and a control device which controls an output voltage of the DC power source so that an electric potential difference between an electric potential of the sample and an electric potential of an inner wall of the plasma processing chamber is reduced to an electric potential difference within a predetermined range during interruption of plasma discharge.

A plasma processing method is implemented by a plasma processing apparatus including a processing chamber, a lower electrode, a focus ring arranged around the lower electrode, an inner upper electrode arranged to face the lower electrode, an outer upper electrode electrically insulated from the inner upper electrode, a quartz member arranged between the inner and outer upper electrodes and above the focus ring, a gas supply unit for supplying gas to the processing chamber, a first high frequency power supply unit for applying a first high frequency power for plasma generation to the lower electrode or the inner and outer upper electrodes, a first direct current power supply unit for applying a variable first direct current voltage to the outer upper electrode, and a control unit. The method includes the control unit controlling the variable first direct current voltage to reduce an amount of change in a tilt angle.

Method for carrying out plasma processing on a wafer under Run-to-Run control by using a plasma processing apparatus having a plasma processing chamber, a process monitor which monitors a condition in the plasma processing chamber, and an actuator which controls parameters which are constituent elements of a plasma processing condition. The method includes the steps of making one of the parameters a (N−1)th manipulated variable, calculating a first difference between a process monitor value in the plasma processing obtained by the process monitor and a desired value of the process monitor value in the plasma processing, calculating a correction amount of the (N−1)th manipulated variable on the basis of the first difference and a previously obtained correlation between the process monitor value in the plasma processing and the (N−1)th manipulated variable, wherein N is a natural number equal to or larger than 2.

In accordance with this disclosure, there are provided several inventions, including a substrate processing apparatus with multi-layer surfaces configured to face the plasma and resist against corrosion. These multi-layer surfaces may in one example include a base layer of aluminum, anodized aluminum, or quartz, a second layer of stabilized zirconia, and a second layer of a yttrium-aluminum composite such as yttrium aluminum garnet (YAG).

An system and method for controlling a plasma chamber includes operably coupling an RF generator to the plasma chamber, the RF generator providing an RF signal to a chamber input of the plasma chamber; measuring a parameter at the chamber input; determining a rate of change based on the measured parameter; detecting an excessive rate of change condition comprising the rate of change exceeding a reference rate of change; detecting a repetitive change condition comprising a predetermined number of the excessive rate of change conditions in a predetermined time; upon detection of the repetitive change condition, decreasing a power of the RF signal provided to the chamber input.

A radio-frequency (RF) generator is provided that includes an exciter, a power amplifier, a filter, a sensor, and a frequency-tuning subsystem. The frequency-tuning subsystem includes a non-transitory, tangible, machine-readable medium containing instructions to perform a method that includes receiving an impedance trajectory of the plasma load; receiving a reference point in a complex-reflection-coefficient plane, the reference point lying on a reference vector passing through the reference point and the origin; receiving, from the sensor, a measured impedance of the plasma load; determining a measurement angle between a reference vector and a line passing through the reference point and a point in the complex-reflection-coefficient plane corresponding to the measured impedance; scaling the measurement angle by a predetermined constant to produce a frequency step; adding the frequency step to the initial frequency to produce an adjusted frequency; and causing the exciter to generate a signal oscillating at the adjusted frequency.

A voltage sensor for a voltage controlled interface of a plasma processing system. The voltage sensor receives a RF signal generated by a pickup device. The RF signal is indicative of a RF voltage provided at a substrate in a plasma chamber. The voltage sensor includes first and second dividers corresponding to first and second channels and having first and second capacitance ratios. The dividers receive the RF signal and respectively generate first and second reduced voltage signals. A first output of the first channel outputs a first output signal based on the first reduced voltage signal and while the RF signal is in a first voltage range. A second output of the second channel outputs a second output signal based on the second reduced voltage signal and while the RF signal is in a second voltage range.