According to one aspect of the present disclosure, a transfer device has a first holding part configured to contact an edge part of a substrate when holding the substrate, and a second holding part formed with an elastic member and configured to contact only a back surface of the substrate when holding the substrate.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a support unit horizontally maintaining a substrate; a laser irradiation unit for irradiating the substrate with a laser; a photo-detector for detecting an energy of a reflective light reflected from the substrate among a laser irradiated on the substrate; and a processor, and wherein the processor irradiates a first laser of a first output to the substrate, and sets a second output of a second laser for irradiating the substrate to heat the substrate, based on an energy of a first reflective light reflected from the substrate by the first laser detected from the photo-detector.

A semiconductor fabrication apparatus comprises a process chamber, an ozone supply that provides the process chamber with ozone, an oxygen supply that provides the ozone supply with a source gas of the ozone, and a plurality of impurity detectors disposed between the oxygen supply and the ozone supply. The impurity detectors detect an inactive gas in the source gas.

A substrate processing chamber includes a housing providing a process space; a spin apparatus provided in the housing; and a fluid spraying nozzle configured to spray fluid into the process space, wherein the spin apparatus includes: a spin chuck configured to support a substrate; a rotation driving part configured to rotate the spin chuck; and a weight sensor configured to measure a weight of the substrate supported on the spin chuck.

There is provided a method of calibrating multiple chamber pressure sensors of a substrate processing system. The substrate processing system includes: multiple chambers; multiple chamber pressure sensors; multiple gas suppliers configured to supply a gas to an internal space of the multiple chambers; multiple exhausters connected to the internal spaces of the multiple chambers via multiple exhaust flow paths; and multiple first gas flow paths. The method includes: acquiring a third volume, which is a sum of a first volume and a second volume; acquiring a first pressure change rate of the internal space of a selected chamber; calculating a second pressure change rate of the internal space of the selected chamber; and calibrating the selected chamber pressure sensor such that a difference between the first pressure change rate and the second pressure change rate is within a preset range.

Described herein is a technique capable of suppressing a deviation in a thickness of a film formed on a substrate. According to one aspect of the technique of the present disclosure, a substrate processing apparatus includes a substrate retainer capable of supporting substrates; a cylindrical process chamber including a discharge part and supply holes; partition parts arranged in the circumferential direction to partition supply chambers communicating with the process chamber through the supply holes; nozzles provided with an ejection hole; and gas supply pipes. The supply chambers includes a first nozzle chamber and a second nozzle chamber, the process gas includes a source gas and an assist gas, the nozzles includes a first nozzle for the assist gas flows and a second nozzle disposed in the second nozzle chamber and through which the source gas flows, and the first nozzle is disposed adjacent to the second nozzle.

Embodiments of the present disclosure generally relate to techniques for deposition of high-density films for patterning applications. In one embodiment, a method of processing a substrate is provided. The method includes depositing a carbon hardmask over a film stack formed on a substrate, wherein the substrate is positioned on an electrostatic chuck disposed in a process chamber, implanting ions into the carbon hardmask, wherein depositing the carbon hardmask and implanting ions into the carbon hardmask are performed in the same process chamber, and repeating depositing the carbon hardmask and implanting ions into the carbon hardmask in a cyclic fashion until a pre-determined thickness of the carbon hardmask is reached.

A process monitor includes a photodetector that separately measures intensities of radiant light from a semiconductor member being annealed, in a plurality of wavelength ranges that are different from each other, and a processing device that obtains a physical quantity related to the semiconductor member that changes due to annealing, based on the intensities in the plurality of wavelength ranges measured by the photodetector.

To facilitate evaluation of a predicted process shape in process recipe development using machine learning, a process recipe search apparatus that searches for an etching recipe that is a parameter of a plasma processing apparatus set so as to etch a sample into a desired shape displays, on a display device, the predicted process shape of the sample by a candidate etching recipe predicted by using a machine leaning model, by highlighting a difference between the predicted process shape and a target shape.

An impedance measurement jig may include a first contact plate, a second contact plate, a cover plate, a plug, and an analyzer. The first contact plate may make electrical contact with an ESC in a substrate-processing apparatus. The second contact plate may make electrical contact with a focus ring configured to surround the ESC. The cover plate may be configured to cover an upper surface of the substrate-processing apparatus. The plug may be installed at the cover plate to selectively make contact with the first contact plate or the second contact plate. The analyzer may individually apply a power to the first contact plate and the second contact plate through the plug to measure an impedance of the ESC and an impedance of the focus ring. Thus, the impedances of the ESC and the focus ring may be individually measured to inspect the ESC and/or the focus ring.