A sensing device for measuring a plasma process parameter in a plasma chamber for processing workpieces may include a substrate with one or more sensor embedded in the substrate. The substrate can have a surface made of substantially the same material as workpieces that are plasma processed in the plasma chamber. Each sensor can include a collector portion made of substantially the same material as the substrate surface. The collector portion includes a surface that is level with the surface of the substrate. The collector portion is the top surface of the substrate. Sensor electronics are embedded into the substrate and coupled to the collector portion. When the substrate surface is exposed to a plasma one or more signals resulting from the plasma can be measured with the sensor(s).

Methods for thermally calibrating reaction chambers are provided. In some embodiments, methods may include calculating a first correction factor of a first contact type temperature sensor within a first reaction chamber utilizing a first temperature sensor and applying the first correction factor to a first temperature controller to provide a first calibrated contact type temperature sensor. Embodiments may also include calculating a first calibration factor of a first non-contact type temperature sensor within the first reaction chamber utilizing the first calibrated contact type temperature sensor and applying the first calibration factor to the first non-contact type temperature sensor to provide a first calibrated non-contact type temperature sensor.

Methods for thermally calibrating reaction chambers are provided. In some embodiments, methods may include calculating a first correction factor of a first contact type temperature sensor within a first reaction chamber utilizing a first temperature sensor and applying the first correction factor to a first temperature controller to provide a first calibrated contact type temperature sensor. Embodiments may also include calculating a first calibration factor of a first non-contact type temperature sensor within the first reaction chamber utilizing the first calibrated contact type temperature sensor and applying the first calibration factor to the first non-contact type temperature sensor to provide a first calibrated non-contact type temperature sensor.

A plasma generation device for generating a plasma comprises a support having a first side and an opposing second side. The support is comprised of a ceramic matrix and a split-ring conductor is embedded in the ceramic matrix. A hermetically sealed via extends from the split-ring conductor to the second side of the support and connects to an electrical supply. A ground plane is formed on the second side of the support. A plasma is generated proximate to the first side of the support, and the support seals to a wall of the chamber such that the first side is exposed to the one or more gases inside the chamber and the second side is isolated from the plasma and the one or more gases inside of the chamber.

Embodiments of method and system for controlling plasma performance are described. In an embodiment a method may include supplying power at a first set of power parameters to a plasma chamber. Additionally, the method may include forming plasma within the plasma chamber using the first set of power parameters. The method may also include measuring power coupling to the plasma at the first set of power parameters. Also, the method may include supplying power at a second set of power parameters to the plasma chamber. The method may additionally include measuring power coupling to the plasma at the second set of power parameters to the plasma. The method may also include adjusting the first set of power parameters based, at least in part, on the measuring of the power coupling at the second set of power parameters.

There is provided an ion generation device including a plasma generation chamber that generates a plasma for extracting an ion, and a heating device configured to heat the plasma generation chamber by irradiating a member that defines the plasma generation chamber or a member that is to be exposed to the plasma generated inside the plasma generation chamber with a laser beam.

Embodiments of method and system for controlling plasma performance are described. In an embodiment a method may include supplying power at a first set of power parameters to a plasma chamber. Additionally, the method may include forming plasma within the plasma chamber using the first set of power parameters. The method may also include measuring power coupling to the plasma at the first set of power parameters. Also, the method may include supplying power at a second set of power parameters to the plasma chamber. The method may additionally include measuring power coupling to the plasma at the second set of power parameters to the plasma. The method may also include adjusting the first set of power parameters based, at least in part, on the measuring of the power coupling at the second set of power parameters.

A vertical semiconductor component for generating an abrupt end point detection signal. The vertical semiconductor component includes: a semiconductor substrate which has a front face and a rear face, the front face being opposite the rear face, and the semiconductor substrate having first chemical elements; a buffer layer which is arranged on the front face of the semiconductor substrate, the buffer layer having second chemical elements; and a semiconductor contact layer which is arranged on the buffer layer, an active region of the vertical semiconductor component being arranged on the semiconductor contact layer. An etching control layer is arranged between the buffer layer and the semiconductor contact layer, the etching control layer having at least one third chemical element which differs from the first chemical elements and the second chemical elements.

Provided is a plasma measuring method for measuring a plasma state using a probe device disposed at a plasma processing apparatus and a measuring circuit including a signal transmitter that outputs an AC voltage, the method comprising: measuring a first current in the measuring circuit when the AC voltage is outputted from the signal transmitter to the probe device in a state where plasma is not generated in the plasma processing apparatus and a second current in a state where plasma is generated in the plasma processing apparatus; measuring a phase difference between a current flowing through the plasma and the AC voltage by vector calculation using the measured first and second currents; and adjusting the AC voltage such that a voltage applied to the plasma becomes constant based on the phase difference and measuring a plasma state based on the measured current flowing through the plasma.

A method of controlling plasma includes providing a plasma processing apparatus that includes N microwave introducing radiators disposed in a circumferential direction of a ceiling plate of a processing container so as to introduce microwaves for generating plasma into the processing container, wherein N?2; and M sensors and configured to monitor at least one of electron density Ne and electron temperature Te of the plasma generated in the processing container, wherein M equals to N or a multiple of N. The method further includes controlling at least one of a power and a phase of the microwaves introduced from the microwave introducing radiators based on at least one of electron density Ne and electron temperature Te of the plasma monitored by the M sensors.