Abstract: A temperature measuring apparatus includes a light source, a first splitter, a second splitter, a reference beam reflector, an optical path length adjuster, a reference beam transmitting member, a first to an nth measuring beam transmitting member and a photodetector. The temperature measuring apparatus further includes an attenuator that attenuates the reference beam reflected from the reference beam reflector to thereby make an intensity thereof closer to an intensity of the measurement beam reflected from the temperature measurement object.

Abstract: A temperature measurement apparatus includes a light source; a first splitter that splits a light beam into a measurement beam and a reference beam; a reference beam reflector that reflects the reference beam; an optical path length adjustor; a second splitter that splits the reflected reference beam into a first reflected reference beam and a second reflected reference beam; a first photodetector that measures an interference between the first reflected reference beam and a reflected measurement beam obtained by the measurement beam reflected from a target object; a second photodetector that measures an intensity of the second reflected reference beam; and a temperature calculation unit. The temperature calculation unit calculates a location of the interference by subtracting an output signal of the second photodetector from an output signal of the first photodetector, and calculates a temperature of the target object from the calculated location of the interference.

Abstract: A temperature measuring apparatus includes a light source, a first splitter, a second splitter, a reference beam reflector, an optical path length adjuster, a reference beam transmitting member, a first to an nth measuring beam transmitting member and a photodetector. The temperature measuring apparatus further includes an attenuator that attenuates the reference beam reflected from the reference beam reflector to thereby make an intensity thereof closer to an intensity of the measurement beam reflected from the temperature measurement object.

Abstract: Provided is a temperature measuring method which can accurately measure a temperature of an object to be measured compared to a conventional method, even if a thin film is formed on the object.

Abstract: The temperature control system includes: a susceptor which allows an object to be processed to be held on a top surface thereof and includes a flow path, through which a temperature adjusting medium flows, formed therein; a temperature measuring unit which measures a temperature of the object to be processed held on the top surface of the susceptor; a first temperature adjusting unit which adjusts a temperature of the temperature adjusting medium flowing through the flow path; and a second temperature adjusting unit which is disposed between the susceptor and the first temperature adjusting unit, and adjusts a temperature of the temperature adjusting medium based on a result of the measurement of the temperature measuring unit.

Abstract: A temperature measurement apparatus includes a light source; a first splitter that splits a light beam into a measurement beam and a reference beam; a reference beam reflector that reflects the reference beam; an optical path length adjustor; a second splitter that splits the reflected reference beam into a first reflected reference beam and a second reflected reference beam; a first photodetector that measures an interference between the first reflected reference beam and a reflected measurement beam obtained by the measurement beam reflected from a target object; a second photodetector that measures an intensity of the second reflected reference beam; and a temperature calculation unit. The temperature calculation unit calculates a location of the interference by subtracting an output signal of the second photodetector from an output signal of the first photodetector, and calculates a temperature of the target object from the calculated location of the interference.

Abstract: The temperature measuring apparatus includes: a light source; a first wavelength-dividing unit which wavelength-divides a light from the light source into m lights whose wavelength bands are different from one another; m first dividing units which divides each of the m lights from the first wavelength-dividing unit into n lights; a transmitting unit which transmits lights from the m first dividing unit to measurement points of an object to be measured; a light receiving unit which receives a light reflected by each of the measurement points; and a temperature calculating unit which calculates a temperature of each of the measurement points based on a waveform of the light received by the light receiving unit.

Abstract: The physical state measuring apparatus includes: a light source; a transmitting unit which transmits a light from the light source to a measurement point of an object to be measured; a nonlinear optical device which changes a wavelength of the light reflected by the measurement point to a wavelength that is different from the wavelength before the changing; a light receiving unit which receives the light whose wavelength has been changed; and a measuring unit which measures a physical state of the object to be measured at the measurement point based on a waveform of the light received by the light receiving unit.

Abstract: A capacitive coupling plasma processing apparatus includes a process chamber configured to have a vacuum atmosphere, and a process gas supply section configured to supply a process gas into the chamber. In the chamber, a first electrode and a second electrode are disposed opposite each other. The second electrode includes a plurality of conductive segments separated from each other and facing the first electrode. An RF power supply is configured to apply an RF power to the first electrode to form an RF electric field within a plasma generation region between the first and second electrodes, so as to turn the process gas into plasma by the RF electric field. A DC power supply is configured to apply a DC voltage to at least one of the segments of the second electrode.

Abstract: A capacitive coupling plasma processing apparatus includes a process chamber configured to have a vacuum atmosphere, and a process gas supply section configured to supply a process gas into the chamber. In the chamber, a first electrode and a second electrode are disposed opposite each other. The second electrode includes a plurality of conductive segments separated from each other and facing the first electrode. An RF power supply is configured to apply an RF power to the first electrode to form an RF electric field within a plasma generation region between the first and second electrodes, so as to turn the process gas into plasma by the RF electric field. A DC power supply is configured to apply a DC voltage to at least one of the segments of the second electrode.

Abstract: There is provided a substrate mounting table capable of accurately measuring a temperature of a wafer supported on the substrate mounting table without incurring contamination within a chamber and without forming a hole for measuring a temperature in the substrate mounting table. The substrate mounting table includes a mounting surface 90a configured to mount a wafer W thereon; a substrate lifting unit 80 configured to lift the wafer W by a lift pin 84 from the mounting surface 90a; and a light irradiating/receiving unit 87 configured to irradiate a measurement light beam 88 as a low-coherence light beam to the wafer W through an inside of the lift pin 84 serving as an optical path and receive reflected light beams from a front surface and a rear surface of the wafer W. The light irradiating/receiving unit 87 is fixed to a base plate 86 of the substrate lifting unit 80.

Abstract: A wear rate measurement method includes thermally coupling a focus ring having a top surface and a bottom surface with a reference piece having a bottom surface facing a susceptor and a top surface facing the focus ring; measuring a first optical path length of a low-coherence light beam that travels forward and backward within the focus ring by irradiating the low-coherence light beam to the focus ring orthogonally to the top surface and the bottom surface thereof; measuring a second optical path length of a low-coherence light beam that travels forward and backward within the reference piece by irradiating the low-coherence light beam to the reference piece orthogonally to the top surface and the bottom surface thereof; and calculating a wear rate of the focus ring based on a ratio between the first optical path length and the second optical path length.

Abstract: A probe for temperature measurement uses interference of a low-coherence light beam. The probe includes a temperature acquiring member configured to be brought into contact with a surface of a temperature measurement target and thermally assimilate with the temperature measurement target; a light irradiating/receiving unit configured to irradiate a measurement light beam as a low-coherence light beam to the temperature acquiring member and receive reflected light beams from a front surface and a rear surface of the temperature acquiring member; and a housing configured to define a distance between the temperature acquiring member and the light irradiating/receiving unit to a preset length and isolate optical paths of the measurement light beam and the two reflected light beams from an atmosphere in which the temperature measurement target is placed.

Abstract: There is provided a method for heating a part within a processing chamber of a semiconductor manufacturing apparatus having a substrate in the processing chamber and performing a process on the substrate. The heating method includes generating heating lights which is generated by a heating light source provided outside the processing chamber and has a wavelength band capable of passing through a first part in the processing chamber and being absorbed into a second part in the processing chamber made of a material different from that of the first part, and heating the second part in the processing chamber by passing the heating lights through the first part in the processing chamber and irradiating the heating lights to the second part in the processing chamber.

Abstract: A temperature measuring apparatus includes a light source, a first splitter, a second splitter, a reference beam reflector, an optical path length adjuster, a reference beam transmitting member, a first to an nth measuring beam transmitting member and a photodetector. The temperature measuring apparatus further includes a controller that stores, as initial peak position data, positions of interference peaks respectively measured in advance by irradiating the first to the nth measuring beam onto the first to the nth measurement point of the temperature measurement object, and compares the initial peak position data to positions of interference peaks respectively measured during a temperature measurement to thereby estimate a temperature at each of the first to the nth measurement point.

Abstract: There are provided a method of heating a focus ring and a plasma etching apparatus, capable of simplifying a structure of a heating mechanism without a dummy substrate. The plasma etching apparatus includes a vacuum processing chamber; a lower electrode serving as a mounting table for mounting a substrate thereon; an upper electrode provided to face the lower electrode; a gas supply unit for supplying a processing gas; a high frequency power supply for supplying a high frequency power to the lower electrode to generate a plasma of the processing gas; and a focus ring provided on the lower electrode to surround a periphery of the substrate. In the plasma etching apparatus, the focus ring is heated by irradiating a heating light thereto from a light source provided outside the vacuum processing chamber.

Abstract: A plasma processing apparatus includes a temperature measuring unit; airtightly sealed temperature measuring windows provided in a mounting table, for optically communicating to transmit a measurement beam through a top surface and a bottom surface of the mounting table; and one or more connection members for connecting the mounting table and a base plate, which is provided in a space between the mounting table and the base plate. In the plasma processing apparatus, a space above the mounting table is set to be maintained under a vacuum atmosphere, and a space between the mounting table and the base plate is set to be maintained under a normal pressure atmosphere, and each collimator is fixed to the base plate at a position corresponding to each temperature measuring window, thereby measuring a temperature of the substrate via the temperature measuring windows by the temperature measuring unit.

Abstract: A plasma processing apparatus for converting a processing gas into a plasma by a high frequency power in a processing chamber and performing a plasma processing on a substrate mounted on a mounting table includes a ring portion disposed to surround the substrate on the mounting table, and a temperature control unit for establishing a temperature difference between the ring portion and the substrate, such that the ring portion is at least 50° C. higher than the substrate. Further, the processing gas generates chlorine radicals, and the temperature control unit is at least one of a heating unit for heating the ring portion and a cooling unit for cooling the mounting table.

Abstract: A focus ring is placed on a substrate mounting table for mounting a target substrate thereon to surround the target substrate. The focus ring converges plasma on the target substrate when the target substrate is subjected to plasma processing. The focus ring is configured to create a temperature difference in its radial direction and over its full circumference during the plasma-processing of the target substrate. The focus ring also includes a radial outer region as a higher temperature region and a radial inner region as a lower temperature region. A groove is formed between the radial outer region and the radial inner region to extend over the full circumference of the focus ring.

Abstract: In a method of controlling the temperature of an in-chamber member used in a plasma processing apparatus that processes a target substrate with plasma, a plurality of power-feeding portions is provided in the in-chamber member and the in-chamber member is heated by supplying electric power thereto through the power-feeding portions. A resistance value or resistivity of the in-chamber member is measured and the electric power is controlled based on the temperature of the in-chamber member estimated from the resistance value or resistivity. The in-chamber member includes one or more annular members arranged around the target substrate. The in-chamber member is a member making contact with plasma within a chamber and existing near the target substrate.