A method is for detecting a condition associated with a final phase of a plasma dicing process. The method includes providing a non-metallic substrate having a plurality of dicing lanes defined thereon, plasma etching through the substrate along the dicing lanes, wherein during the plasma etching infrared emission emanating from at least a portion of the dicing lanes is monitored so that an increase in infrared emission from the dicing lanes is observed as the final phase of the plasma dicing operation is entered, and detecting the condition associated with the final phase of the plasma dicing from the monitored infrared emission.

To provide a wavelength selection method or a plasma processing method to achieve accurate detection of residual thickness or etching amount, there is provided a plasma processing method, in which a processing object wafer is disposed within a processing chamber in the inside of a vacuum container, and plasma is generated by supplying a processing gas into the processing chamber and used to process a processing-object film layer beforehand formed on a surface of the wafer, and at least two wavelengths are selected from among wavelengths with large mutual information in emission of a plurality of wavelengths of plasma generated during processing of the processing-object film layer, and a temporal change in the emission of at least the two wavelengths is detected, and an endpoint of the processing of the film layer is determined based on a result of the detection.

A white light illumination source can illuminate a region of a substrate to be plasma etched with an incident light beam. A camera takes successive images of the region being illuminated during a plasma etch process. Image processing techniques can be applied to the images so as to identify a location of at least one feature on the substrate and to measure a reflectivity signal at the location. The plasma etch process can be modified in response to the measured reflectivity signal at the location.

A system includes a reflector attached to a liner of a processing chamber. A light coupling device is to transmit light, from a light source, through a window of the processing chamber directed at the reflector. The light coupling device focuses, into a spectrometer, light received reflected back from the reflector along an optical path through the processing chamber and the window. The spectrometer detects, within the focused light, a first spectrum representative of a deposited film layer on the reflector using reflectometry. An alignment device aligns, in two dimensions, the light coupling device with the reflector until maximization of the focused light received by the light coupling device.

The invention provides a method and system to remotely monitor a plasma (3) comprising a magnetic field antenna (2) positioned in the near electromagnetic field of a coupled plasma source wherein the magnetic field antenna is a magnetic loop antenna placed in the near electromagnetic field and measure near field signals emitted from the plasma source. A radio system (1) is utilised to analyse the low power signal levels across a wide frequency band. Plasma paramaters such as series, or geometric, resonance plasma and electron-neutral collision frequencies are evaluated via a fitting of resonant features present on higher harmonics of the driving frequency to identify arcing, pump or matching failure events, common in fabrication plasma systems.

The present application discloses a semiconductor manufacturing apparatus, including: a chamber including an inner chamber, an outer chamber and a passage communicating the inner chamber with the outer chamber, the passage being located between the inner chamber and a chamber sidewall; and one or more electrodes disposed in the chamber sidewall and configured to ionize a treating gas coming from the inner chamber to generate plasma so as to clean off deposit produced in the inner chamber.

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 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 substrate processing system for selectively etching a substrate includes a first chamber and a second chamber. A first gas delivery system supplies an inert gas species to the first chamber. A plasma generating system generates plasma including ions and metastable species in the first chamber. A gas distribution device removes the ions from the plasma, blocks ultraviolet (UV) light generated by the plasma and delivers the metastable species to the second chamber. A substrate support is arranged below the gas distribution device to support the substrate. A second gas delivery system delivers a reactive gas species to one of the gas distribution device or a volume located below the gas distribution device. The metastable species transfer energy to the reactive gas species to selectively etch one exposed material of the substrate more than at least one other exposed material of the substrate.

A wide-gap semiconductor substrate enables formation of a device having low power loss while maintaining high mechanical strength. The wide-gap semiconductor substrate (70) is obtained by placing a wide-gap semiconductor substrate onto a platen (15) disposed in a processing chamber (11) and etching and thinning only a first substrate region (70a), where a device (50) is formed, of the wide-gap semiconductor substrate by means of plasma generated from an etching gas. In the wide-gap semiconductor substrate (70), a connecting portion as a peripheral edge of the first substrate region (70a) connecting to a second substrate region (70b) surrounding the first substrate region (70a) includes an arc portion having a predetermined radius of curvature.