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 temperature measuring apparatus and a temperature measuring method that may simultaneously measure temperatures of objects in processing chambers. The temperature measuring apparatus includes a first light separating unit which divides light from the light source into measurement lights; second light separating units which divide the measurement lights from the first light separating unit into measurement lights and reference lights; third light separating units which further divide the measurement lights into first to n-th measurement lights; a reference light reflecting unit which reflects the reference lights; an light path length changing unit which changes light path lengths of the reference lights reflected by the reference light reflecting unit; and photodetectors which measure interference between the first to n-th measurement lights reflected by the objects to be measured and the reference lights reflected by the reference light reflecting unit.

Abstract: A plasma processing apparatus includes a process container configured to accommodate a target substrate and to be vacuum-exhausted. A first electrode and a second electrode are disposed opposite each other within the process container. The first electrode includes an outer portion and an inner portion both facing the second electrode such that the outer portion surrounds the inner portion. An RF power supply is configured to apply an RF power to the outer portion of the first electrode. A DC power supply is configured to apply a DC voltage to the inner portion of the first electrode. A process gas supply unit is configured to supply a process gas into the process container, wherein plasma of the process gas is generated between the first electrode and the second electrode.

Abstract: A component in a processing chamber of a substrate processing apparatus, where a temperature may be accurately measured by using a temperature measuring apparatus using an interference of a low-coherence light, even when a front surface and a rear surface are not parallel due to abrasion, or the like. A focus ring used in a vacuum atmosphere and of which a temperature is measured includes an abrasive surface exposed to an abrasive atmosphere according to plasma, a nonabrasive surface not exposed to the abrasive atmosphere, a thin-walled portion including a top surface and a bottom surface that are parallel to each other, and a coating member coating the top surface of the thin-walled portion, wherein a mirror-like finishing is performed on each of the top and bottom surfaces of the thin-walled portion.

Abstract: In a plasma processing apparatus, a first electrode is attached to a grounded evacuable processing chamber via an insulating material or a space and a second electrode disposed in parallel with the first electrode spaced apart therefrom in the processing chamber, the second electrode supporting a target substrate to face the first electrode. A first radio frequency power supply unit applies a first radio frequency power of a first frequency to the second electrode, and a second radio frequency power supply unit applies a second radio frequency power of a second frequency lower than the first frequency to the second electrode. Further, a processing gas supply unit supplies a processing gas to a processing space formed by the first and the second electrode and a sidewall of the processing chamber. Moreover, an inductor electrically is connected between the first electrode and a ground potential.

Abstract: A plasma processing apparatus includes a process container configured to accommodate a target substrate and to be vacuum-exhausted. A first electrode and a second electrode are disposed opposite each other within the process container. The first electrode includes an outer portion and an inner portion both facing the second electrode such that the outer portion surrounds the inner portion. An RF power supply is configured to apply an RF power to the outer portion of the first electrode. A DC power supply is configured to apply a DC voltage to the inner portion of the first electrode. A process gas supply unit is configured to supply a process gas into the process container, wherein plasma of the process gas is generated between the first electrode and the second electrode.

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 for processing a substrate by using a plasma includes a processing chamber for accommodating and processing the substrate therein, a lower electrode for mounting the substrate thereon in the processing chamber, an upper electrode disposed to face the lower electrode in the processing chamber, a radio frequency power supply for supplying a radio frequency power to at least one of the lower and the upper electrode, to thereby generate the plasma between the lower and the upper electrode, and an electrical characteristic control unit for adjusting an impedance of a circuit at the side of an electrode to the plasma for a frequency of at least one radio frequency wave present in the processing chamber such that the circuit does not resonate.

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.

Abstract: An optimum application voltage for reducing deposits on a peripheral portion of a substrate as well as improving a process result in balance is effectively found without changing a height of a focus ring. A plasma processing apparatus includes a focus ring which includes a dielectric ring provided so as to surround a substrate mounting portion of a mounting table and a conductive ring provided on the dielectric ring; a voltage sensor configured to detect a floating voltage of the conductive ring; a DC power supply configured to apply a DC voltage to the conductive ring. An optimum voltage to be applied to the conductive ring is obtained based on a floating voltage actually detected from the conductive ring, and the optimum application voltage is adjusted based on a variation in the actually detected floating voltage for each plasma process.

Abstract: A plasma processing apparatus includes a plurality of radio-frequency power supplies for supplying radio-frequency powers having frequencies different from each other, a common feeding line for superposing radio-frequency powers supplied respectively from the plurality of radio-frequency power supplies and feeding the superposed radio-frequency power to a same radio-frequency electrode, a radio-frequency power extracting device for extracting radio-frequency powers having predetermined frequencies from radio-frequency powers fed via the feeding line, and a radio-frequency voltage detector for measuring voltages of the radio-frequency powers having the predetermined frequencies extracted by the radio-frequency power extracting device.

Abstract: A plasma processing apparatus includes a processing chamber, a first electrode and a second electrode disposed to face each other, a high frequency power supply unit for applying a high frequency power to either the first electrode or the second electrode, a processing gas supply unit for supplying a processing gas to a processing space, and a main dielectric member provided at a substrate mounting portion on a main surface of the first electrode. A focus ring is attached to the first electrode to cover a peripheral portion of the main surface of the first electrode and a peripheral dielectric member is provided in a peripheral portion on the main surface of the first electrode so that an electrostatic capacitance per unit area applied between the first electrode and the focus ring is smaller than that applied between the first electrode and the substrate by the main dielectric member.

Abstract: A plasma processing apparatus, which generates a plasma by a radio frequency discharge in a processing chamber, includes a first member having a first front surface facing the plasma, and a first mating surface extending from the first front surface; and a second member having a second front surface that forms an angled portion together with the first front surface of the first member in a manner to face the plasma, and a second mating surface facing the first mating surface of the first member with a gap therebetween. In the angled portion, an opening portion of gap and an inner portion extending from the opening portion to at least an intermediate location of the gap are oriented along an extended straight line that bisects an angle between the first front surface of the first member and the second front surface of the second member.

Abstract: A plasma processing apparatus can prevent a sheath from becoming distorted, simplify a configuration of the apparatus, and prevent particles from attaching to a substrate. The plasma processing apparatus performs plasma processing on the substrate. A housing chamber houses the substrate. A mounting stage is disposed within the housing chamber and mounted with the substrate. An annular member is disposed in the mounting stage. A power supply unit supplies high-frequency power to the mounting stage. An observation unit optically observes the distribution of the plasma. A voltage applying unit applies a DC voltage to the annular member. A control unit sets the value of the DC voltage to be applied based on the observed plasma distribution.

Abstract: A plasma processing apparatus includes a processing chamber, a first electrode and a second electrode disposed to face each other, a high frequency power supply unit for applying a high frequency power to either the first electrode or the second electrode, a processing gas supply unit for supplying a processing gas to a processing space, and a main dielectric member provided at a substrate mounting portion on a main surface of the first electrode. A focus ring is attached to the first electrode to cover a peripheral portion of the main surface of the first electrode and a peripheral dielectric member is provided in a peripheral portion on the main surface of the first electrode so that an electrostatic capacitance per unit area applied between the first electrode and the focus ring is smaller than that applied between the first electrode and the substrate by the main dielectric member.

Abstract: A plasma processing apparatus includes: a vacuum-evacuable processing chamber; a lower central electrode; a lower peripheral electrode surrounding the lower central electrode in an annular shape; an upper electrode provided to face the lower central electrode and the lower peripheral electrode; a processing gas supply unit for supplying a processing gas into the processing chamber; an RF power supply for outputting an RF power for generating a plasma; and a power feed conductor connected to a rear surface of the lower peripheral electrode to supply the RF power to the lower peripheral electrode. The apparatus further includes a variable capacitance coupling unit for electrically connecting the lower central electrode with at least one of the power feed conductor and the lower peripheral electrode by capacitance coupling with a variable impedance in order to supply a part of the RF power from the RF power supply to the lower central electrode.

Abstract: A component in a processing chamber of a substrate processing apparatus, where a temperature may be accurately measured by using a temperature measuring apparatus using an interference of a low-coherence light, even when a front surface and a rear surface are not parallel due to abrasion, or the like. A focus ring used in a vacuum atmosphere and of which a temperature is measured includes an abrasive surface exposed to an abrasive atmosphere according to plasma, a nonabrasive surface not exposed to the abrasive atmosphere, a thin-walled portion including a top surface and a bottom surface that are parallel to each other, and a coating member coating the top surface of the thin-walled portion, wherein a mirror-like finishing is performed on each of the top and bottom surfaces of the thin-walled portion.

Abstract: Disclosed is a capacitively-coupled plasma etching apparatus, in which a focus ring is provided surrounding a substrate placing area of a placing table for adjusting a state of plasma. A ring type insulating member is installed along the focus ring between the top surface of the placing table and the bottom surface of the focus ring, and a heat transfer member is installed between the top surface of the placing table and the bottom surface of the focus ring to be closely attached to the top surface and the bottom surface at a position adjacent to the insulating member in a diameter direction of a wafer. During the plasma processing, the heat in the focus ring is transferred to the placing table through the heat transfer member to be cooled down and the amount of sediment attached to the rear surface of the wafer can be reduced.

Abstract: A temperature measuring apparatus and a temperature measuring method that may simultaneously measure temperatures of objects in processing chambers. The temperature measuring apparatus includes a first light separating unit which divides light from the light source into measurement lights; second light separating units which divide the measurement lights from the first light separating unit into measurement lights and reference lights; third light separating units which further divide the measurement lights into first to n-th measurement lights; a reference light reflecting unit which reflects the reference lights; an light path length changing unit which changes light path lengths of the reference lights reflected by the reference light reflecting unit; and photodetectors which measure interference between the first to n-th measurement lights reflected by the objects to be measured and the reference lights reflected by the reference light reflecting unit.

Abstract: In the plasma processing apparatus 10, a processing space S is formed between a susceptor 12 and an upper electrode 13 facing the susceptor 12. The plasma processing apparatus 10 includes a magnetic field generating unit provided at a side of the upper electrode 13 opposite to the processing space S. The magnetic field generating unit includes a magnetic force line generating unit 27 having a pair of annular magnet rows 27a and 27b. The annular magnet rows 27a and 27b are provided at the side of the upper electrode 13 opposite to the processing space S and arranged concentrically when viewed from the top. In the magnetic force line generating unit 27, an angle ?1 formed by axial lines of magnets of the annular magnet rows 27a and 27b is set to be in a range of about 0°<?1?180°.