Abstract: A plasma processing apparatus with improved yield, adapted to include a vacuum container, a processing chamber disposed inside thereof, and in which a plasma is formed, a sample table disposed in the processing chamber and on which a sample is placed, two electrodes which have a film shape, disposed within the sample table, and to which power for attracting the sample is supplied so that different polarities are formed, a coiled portion in which two power supply lines are wound in parallel around the same axis, and a bypass line which connects the two power supply lines between the coiled portion and the two electrodes and has a capacitor.

Abstract: A plasma processing device in which plasma processing uniformity is improved up to an outer peripheral portion of a wafer and the number of non-defective devices that can be manufactured from one wafer is increased. The plasma processing device includes a vacuum container; a mounting table, a susceptor ring that covers an outer peripheral portion of an electrode base material, and an insulation ring covered by the susceptor ring and surrounding the electrode base material, and thin film electrode formed on an upper surface and a part of a surface facing the outer periphery of the electrode base material; a first high frequency power applied to the electrode base material a second high frequency power applied to the thin film electrode; a plasma generating unit that generates plasma on an upper portion of the mounting table inside the vacuum container; and a control unit.

Abstract: A plasma processing apparatus includes a sample stage on which a sample is placed an inside of the processing chamber; a dielectric membrane forming an upper surface portion of the sample stage; a plurality of film-shaped electrodes which is disposed in the dielectric membrane, to which a DC power from a DC power supply is supplied and in which an electrostatic force for attracting the sample is formed; and a bias electrode (ESC base metal) disposed below the dielectric membrane and supplied with radio frequency power for forming a radio frequency bias potential from a radio frequency power supply during the processing of the sample.

Abstract: A plasma processing apparatus improves uniformity of a plasma in a radial direction, generation efficiency of plasma, and a yield of a process, and the apparatus includes a sample stage which includes a dielectric susceptor ring located surrounding a top surface of the sample stage on an outer peripheral and a dielectric lower ring-shaped plate located at a position lower than a top surface of the susceptor ring on its outer peripheral side. A difference in height between the top surfaces of the lower ring-shaped plate and the sample is set in a range of around 5 mm of a value found by a formula using a distance: G [mm] between the upper and the lower electrodes, a frequency: f [MHz] of a first high-frequency power, and a pressure: P [Pa] in the processing chamber, and ?0.1×G?0.06×f?4.4×ln(P)+22.

Abstract: A plasma processing apparatus including: a processing chamber; a sample stage; a vacuum exhaust unit; and a plasma generation unit, the sample stage includes: a first metallic base material having a refrigerant flow path formed therein; a second metallic base material disposed above the first metallic base material and has a lower thermal conductivity than the first metallic base material; and a plurality of lift pins vertically moving the object to be processed with respect to the sample stage. A plurality of through-holes through which the plurality of the lift pins passes is formed in the first and the second metallic base material, and a boss, which electrically insulates the lift pin from the first and the second metallic base material and is formed using an insulating member having a higher thermal conductivity than the second metallic base material, is inserted into each of the plurality of through-holes.

Abstract: Provided is a plasma processing apparatus in which a sample as a processing target placed and held on a sample stage is processed using plasma formed inside a processing chamber, the sample stage being disposed inside the processing chamber inside a vacuum chamber, wherein a plate-like member, which is disposed on the sample stage, constitutes a top surface placed with the sample, and is formed of a first dielectric, includes: an outer circumferential protruding portion disposed in a ring shape surrounding a central portion on the top surface of the plate-like member along an outer circumferential edge; a plurality of columnar projections which are arranged on the top surface of the plate-like member on the central side of the outer circumferential protruding portion; and a film formed of a second dielectric which covers the top surface of the plate-like member on the central side of the outer circumferential protruding portion, a top-portion top surface of the projections, and a top surface of the plate-like

Abstract: Provided is a plasma processing apparatus including: a processing chamber; a sample stage placed inside the processing chamber; a processing gas supply unit which supplies processing gas into the processing chamber; a high-frequency power supply which supplies an electric field inside the processing chamber; an electrostatic chuck unit disposed on the sample stage in which openings to flow heat transfer gas are formed; a refrigerant supply unit which supplies a refrigerant inside the sample stage; and a control unit, wherein the control unit controls a heat transfer gas supply unit to control the temperature of a wafer depending on a plurality of processes for processing the wafer by switching a flow rate of the heat transfer gas or the type of the heat transfer gas flowing out of the openings between a concave portion formed in the electrostatic chuck unit and the wafer attracted to the electrostatic chuck unit.

Abstract: The reliability of a plasma processing apparatus can be improved, and the yield of plasma processing can be improved. A plasma etching apparatus 100 has a susceptor ring 113 covering the surface of a sample stage, a conductor ring 131 disposed in the interior of the susceptor ring 113 and to which second high frequency electric power is supplied from a second high frequency power source, and an electric power supply connector 161 configuring a path for supplying the second high frequency electric power to the conductor ring 131. Further, the electric power supply connector 161 includes a plate spring 135 disposed in the interior of an insulating boss 144 disposed in a through hole 120c of the sample stage and having resiliency in such a manner that the plate spring 135 is connected to an upper terminal 143 and a lower terminal 145, is biased in an up-down direction P, and is expanded and contracted.

Abstract: A plasma processing apparatus includes: a processing room disposed inside a vacuum chamber; a sample stage disposed inside the processing room, having an upper surface on which a wafer to be processed is to be mounted; a dielectric discoid member opposed to the upper surface of the sample stage in an upper part of the processing room; a discoid upper electrode disposed having a side covered with the discoid member, the side facing the sample stage, the discoid upper electrode being to be supplied with first radio-frequency power for forming an electric field for forming plasma in the processing room; a coil disposed circumferentially above the processing room outside the vacuum chamber, the coil being configured to generate a magnetic field for forming the plasma; and a lower electrode disposed inside the sample stage, the lower electrode being to be supplied with second radio-frequency power for forming a bias potential on the wafer mounted on the sample stage.

Abstract: A plasma processing apparatus or a plasma processing method that processes a wafer to be processed, which is placed on a surface of a sample stage arranged in a processing chamber inside a vacuum container, using a plasma formed in the processing chamber, the apparatus or method including processing the wafer by adjusting a first high-frequency power to be supplied to a first electrode arranged inside the sample stage and a second high-frequency power to be supplied, via a resonant circuit, to a second electrode which is arranged in an inner side of a ring-shaped member made of a dielectric arranged on an outer peripheral side of a surface of the sample stage on which the wafer is placed, during the processing.

Abstract: The present invention is a manufacturing method for manufacturing a magnetoresistive element, including a first step for oxidizing or reducing a magnetic film constituting the magnetoresistive element and a metal oxidation film constituting the magnetoresistive element, and a second step performed after the first step, wherein in the second step, in a case where the magnetic film constituting the magnetoresistive element and the metal oxidation film constituting the magnetoresistive element are oxidized, the oxidized magnetic film constituting the magnetoresistive element or the oxidized metal oxidation film constituting the magnetoresistive element is selectively reduced, and in a case where the magnetic film constituting the magnetoresistive element and the metal oxidation film constituting the magnetoresistive element are reduced, the reduced magnetic film constituting the magnetoresistive element or the reduced metal oxidation film constituting the magnetoresistive element is selectively oxidized.

Abstract: A plasma processing apparatus or a plasma processing method that processes a wafer to be processed, which is placed on a surface of a sample stage arranged in a processing chamber inside a vacuum container, using a plasma formed in the processing chamber, the apparatus or method including processing the wafer by adjusting a first high-frequency power to be supplied to a first electrode arranged inside the sample stage and a second high-frequency power to be supplied, via a resonant circuit, to a second electrode which is arranged in an inner side of a ring-shaped member made of a dielectric arranged on an outer peripheral side of a surface of the sample stage on which the wafer is placed, during the processing.

Abstract: A vacuum processing apparatus includes a processing chamber inside a vacuum vessel, a plasma forming chamber above, a dielectric plate member having multiple through-holes for introducing particles of plasma to the processing chamber between the processing chamber and the plasma forming chamber above a sample stage upper surface in the processing chamber, heating lamp arranged around an outer periphery of the plate member to irradiate an electromagnetic wave to the wafer to heat, and a ring-shaped window member for transmitting the electromagnetic wave from the lamp. The apparatus performs, from the through-holes to the wafer, supplying particles of plasma formed in the plasma forming chamber to form a reaction product, extinguishing the plasma and heating the wafer to desorb the product, and supplying particles, formed in the plasma forming chamber, of the plasma of cleaning gas to the plasma forming chamber, the processing chamber, and the window member.

Abstract: In a plasma processing apparatus, a connector section with the film-like electrode of a sintered plate of a sample stage to which high-frequency power is supplied includes a conductor section disposed inside a through hole, an upper part of which is bonded to the film-like electrode and a lower part of which is connected to an end of a power supply path of the high-frequency power, and a boss disposed between the conductor section and a substrate surrounding an outer periphery of the conductor section inside the through hole and made of an insulating material. Upper ends of a rod-like member at the center of the conductor section and a socket surrounding the rod-like member are disposed at a position higher than the boss, and an adhesive is prevented from entering between the socket and the rod-like member in the upper end of the socket.

Abstract: A plasma processing apparatus includes a stage disposed in a processing chamber for mounting a wafer, a plasma generation chamber disposed above the processing chamber for plasma generation using process gas, a plate member having multiple introduction holes, made of a dielectric material, disposed above the stage and between the processing chamber and the plasma generation chamber, and a lamp disposed around the plate member for heating the wafer. The plasma processing apparatus further includes an external IR light source, an emission fiber arranged in the stage, that outputs IR light from the external IR light source toward a wafer bottom, and a light collection fiber for collecting IR light from the wafer. Data obtained using only IR light from the lamp is subtracted from data obtained also using IR light from the external IR light source during heating of the wafer. Thus, a wafer temperature is determined.

Abstract: A vacuum processing apparatus includes a processing chamber inside a vacuum vessel, a plasma forming chamber above, a dielectric plate member having multiple through-holes for introducing particles of plasma to the processing chamber between the processing chamber and the plasma forming chamber above a sample stage upper surface in the processing chamber, heating lamp arranged around an outer periphery of the plate member to irradiate an electromagnetic wave to the wafer to heat, and a ring-shaped window member for transmitting the electromagnetic wave from the lamp. The apparatus performs, from the through-holes to the wafer, supplying particles of plasma formed in the plasma forming chamber to form a reaction product, extinguishing the plasma and heating the wafer to desorb the product, and supplying particles, formed in the plasma forming chamber, of the plasma of cleaning gas to the plasma forming chamber, the processing chamber, and the window member.