Abstract: A cleaning method according to the present disclosure includes a first cleaning operation and a second cleaning operation, wherein the first cleaning operation includes: supplying a first processing gas to the interior of the chamber; and cleaning a region including the placement region of the stage by generating a first plasma from the first processing gas in a space defined by the placement region and the electrode, and the second cleaning operation includes: holding a dummy substrate at a predetermined position spaced by a predetermined distance from the placement region to face the placement region; supplying a second processing gas to the interior of the chamber; and cleaning a region including a periphery of the placement region of the stage by generating a second plasma from the second processing gas in a space defined by the dummy substrate held at the predetermined position and the electrode.

Abstract: A method of cleaning a stage in a plasma processing apparatus including the stage on which a substrate is placed, a lifting mechanism configured to raise and lower the substrate with respect to the stage, and a high-frequency power supply connected to the stage, includes: separating the stage and the substrate from each other using the lifting mechanism; and after the separating the stage and the substrate from each other, removing a deposit deposited on the stage with plasma generated by supplying a high-frequency power from the high-frequency power supply to the stage. In the separating the stage and the substrate from each other, a separation distance between the stage and the substrate is set such that a combined impedance formed around an outer peripheral portion of the stage is lower than a combined impedance formed immediately above a central portion of the stage.

Abstract: A method of cleaning a stage in a plasma processing apparatus including the stage on which a substrate is placed, a lifting mechanism configured to raise and lower the substrate with respect to the stage, and a high-frequency power supply connected to the stage, includes: separating the stage and the substrate from each other using the lifting mechanism; and after the separating the stage and the substrate from each other, removing a deposit deposited on the stage with plasma generated by supplying a high-frequency power from the high-frequency power supply to the stage. In the separating the stage and the substrate from each other, a separation distance between the stage and the substrate is set such that a combined impedance formed around an outer peripheral portion of the stage is lower than a combined impedance formed immediately above a central portion of the stage.

Abstract: A method of cleaning a stage in a plasma processing apparatus including the stage on which a substrate is placed, a lifting mechanism configured to raise and lower the substrate with respect to the stage, and a high-frequency power supply connected to the stage, includes: separating the stage and the substrate from each other using the lifting mechanism; and after the separating the stage and the substrate from each other, removing a deposit deposited on the stage with plasma generated by supplying a high-frequency power from the high-frequency power supply to the stage. In the separating the stage and the substrate from each other, a separation distance between the stage and the substrate is set such that a combined impedance formed around an outer peripheral portion of the stage is lower than a combined impedance formed immediately above a central portion of the stage.

Abstract: A plasma processing method is provided that includes a step of loading a substrate into a chamber where a plasma process is to be executed, a step of applying a high frequency bias power that has a lower frequency than a high frequency excitation power for plasma excitation to a mounting table on which the substrate is mounted, and a step of applying a DC voltage to an electrostatic chuck configured to electrostatically attract the substrate that is mounted on the mounting table. The step of applying the DC voltage is performed after the step of applying the high frequency bias power.

Abstract: A substrate transfer apparatus includes a transfer chamber in which a substrate is transferred, and a process chamber configured to process a substrate therein. A contamination monitor is provided in the transfer chamber and configured to detect a contamination condition of the transfer chamber.

Abstract: A plasma processing method is provided that includes a step of loading a substrate into a chamber where a plasma process is to be executed, a step of applying a high frequency bias power that has a lower frequency than a high frequency excitation power for plasma excitation to a mounting table on which the substrate is mounted, and a step of applying a DC voltage to an electrostatic chuck configured to electrostatically attract the substrate that is mounted on the mounting table. The step of applying the DC voltage is performed after the step of applying the high frequency bias power.

Abstract: A plasma processing method of the present disclosure includes attaching a Si-containing material or a N-containing material to an electrostatic chuck that is provided in a processing container and attached with a reaction product containing C and F, in a state where a workpiece is not mounted on the electrostatic chuck; adsorbing the workpiece by the electrostatic chuck attached with the Si-containing material or the N-containing material when the workpiece is carried into the processing container; processing the workpiece with plasma; and separating the workpiece processed with plasma from the electrostatic chuck attached with the Si-containing material or the N-containing material.

Abstract: A plasma processing method of the present disclosure includes attaching a Si-containing material or a N-containing material to an electrostatic chuck that is provided in a processing container and attached with a reaction product containing C and F, in a state where a workpiece is not mounted on the electrostatic chuck; adsorbing the workpiece by the electrostatic chuck attached with the Si-containing material or the N-containing material when the workpiece is carried into the processing container; processing the workpiece with plasma; and separating the workpiece processed with plasma from the electrostatic chuck attached with the Si-containing material or the N-containing material.

Abstract: A Ti-based film forming method includes a step (step 1) of cleaning inside a chamber by introducing a cleaning gas containing fluorine into the chamber in a state where a wafer W is not provided on a susceptor; a step (step 2) of heating the susceptor in a state where the wafer W is not provided on the susceptor, injecting a processing gas containing Ti from a shower head into the chamber, and forming a pre-coated film at least on the surface of the shower head; and a step (step 3) of mounting the wafer W on the susceptor 2 in a state where the susceptor is heated, supplying a processing gas into the chamber 1 and forming a Ti-based film on the wafer W. The pre-coated film forming step is performed at a temperature lower than that in the film forming step.

Abstract: A Ti-based film forming method includes a step (step 1) of cleaning inside a chamber by introducing a cleaning gas containing fluorine into the chamber in a state where a wafer W is not provided on a susceptor; a step (step 2) of heating the susceptor in a state where the wafer W is not provided on the susceptor, injecting a processing gas containing Ti from a shower head into the chamber, and forming a pre-coated film at least on the surface of the shower head; and a step (step 3) of mounting the wafer W on the susceptor 2 in a state where the susceptor is heated, supplying a processing gas into the chamber 1 and forming a Ti-based film on the wafer W. The pre-coated film forming step is performed at a temperature lower than that in the film forming step.

Abstract: A temperature measuring device includes an optical fiber, a metallic protective tube covering the optical fiber, and a heat insulation coating covering the metallic protective tube such that the optical fiber is covered with the metallic protective tube and the heat insulation coating to form a double-covered optical fiber. The heat insulation coating contains carbon particles as an additive. In addition, a radiation thermometer is connected to the double-covered optical fiber, and a tip of the double-covered optical fiber forms a temperature measuring element for collecting and transmitting radiation to the radiation thermometer.

Abstract: A method and apparatus for measuring a true temperature using a consumable optical fiber, wherein received light emitted from a high temperature liquid is divided into two light beams through a branching filter. A light of a first wave band from a first light beam of the two light beams is detected by a first radiation thermometer, and the light of the first wave band is converted into temperature to output a first temperature. A light of a second wave band from a second light beam of the two light beams is detected by a second radiation thermometer, and the light of the second wave band is converted into temperature to output a second temperature.

Abstract: An ellipsometer has a nonpolarization beam splitter (18) for dividing reflected light (17) from an object to be measured (16) into portions traveling along first and second optical paths (18a, 18b), an analyzer (19) for passing the polarized light component in a reference direction of the reflected light portion traveling along the first optical path, and a polarization beam splitter (20) for dividing the reflected light portion traveling along the second optical path into two polarized light components in different directions with respect to the reference direction. The light beams passing through the analyzer (19) and polarization beam splitter (20) are sensed by first, second and third photodetectors (21a, 21b, 21c), respectively. In a coating thickness control method, first and second ellipsometers (35a, 35b) are placed before and after a coating apparatus (36) provided along the transport path of a belt-like plate to be coated (31). A first ellipsoparameter (.DELTA.1,.psi.