Abstract: There is provided an inductively coupled plasma processing apparatus capable of reducing a RF power loss within a high frequency power supply unit (particularly, a matching unit) and capable of enhancing a plasma generation efficiency. In this inductively coupled plasma processing apparatus, a multiple number of closed-loop secondary circuits 96, 98 independent from each other are formed between a coaxial antenna group 54 and a transformer 68. Further, by varying electrostatic capacitances of variable capacitors 64 and 66, secondary currents I2A and I2B flowing through an inner antenna 58 and an outer antenna 60, respectively, of the coaxial antenna group 54 are independently controlled. Accordingly, it is possible to readily control a plasma density distribution on a semiconductor wafer W in a diametrical direction.

Abstract: An apparatus includes an upper electrode and a lower electrode for supporting a wafer disposed opposite each other within a process chamber. A first RF power supply configured to apply a first RF power having a relatively higher frequency is connected to the upper electrode. A second RF power supply configured to apply a second RF power having a relatively lower frequency is connected to the lower electrode. A variable DC power supply is connected to the upper electrode. A process gas is supplied into the process chamber while any one of application voltage, application current, and application power from the variable DC power supply to the upper electrode is controlled, to generate plasma of the process gas so as to perform plasma etching.

Abstract: A plasma etching apparatus includes an upper electrode and a lower electrode, between which plasma of a process gas is generated to perform plasma etching on a wafer W. The apparatus further comprises a cooling ring disposed around the wafer, a correction ring disposed around the cooling ring, and a variable DC power supply directly connected to the correction ring, the DC voltage being preset to provide the correction ring with a negative bias, relative to ground potential, for attracting ions in the plasma and to increase temperature of the correction ring to compensate for a decrease in temperature of a space near the edge of the target substrate due to the cooling ring.

Abstract: A plasma processing apparatus includes a vacuum evacuable processing chamber, at least a portion of which is formed of a dielectric window; a substrate supporting unit for supporting a target substrate in the processing chamber; and a processing gas supply unit for supplying a desired processing gas into the processing chamber. Further, the plasma processing apparatus includes an RF antenna provided outside the dielectric window; a high frequency power supply unit for supplying to the RF antenna a high frequency power; and a switching network switched among a parallel mode, a multiplication series mode, and a minimization series mode.

Abstract: An apparatus includes an upper electrode and a lower electrode for supporting a wafer disposed opposite each other within a process chamber. A first RF power supply configured to apply a first RF power having a relatively higher frequency, and a second RF power supply configured to apply a second RF power having a relatively lower frequency is connected to the lower electrode. A variable DC power supply is connected to the upper electrode. A process gas is supplied into the process chamber to generate plasma of the process gas so as to perform plasma etching.

Abstract: In the present invention, two coil-shaped probes each detecting the intensity of a magnetic field in a direction around a center axis of a processing space are provided in a process vessel of a plasma processing apparatus. Each of the probes detects an induced electromotive force generated in the coil, and a computer calculates an amount of radio-frequency current from the induced electromotive force, based on a predetermined calculation principle. A difference between the amounts of the radio-frequency current detected by the probes is calculated, and a loss radio-frequency current amount passing out of a plasma area between upper and lower electrodes is calculated, whereby the flow of the radio-frequency current in the plasma is known.

Abstract: A plasma etching apparatus includes an upper electrode and a lower electrode, between which plasma of a process gas is generated to perform plasma etching on a wafer W. The apparatus further comprises a cooling ring disposed around the wafer, a correction ring disposed around the cooling ring, and a variable DC power supply directly connected to the correction ring, the DC voltage being preset to provide the correction ring with a negative bias, relative to ground potential, for attracting ions in the plasma and to increase temperature of the correction ring to compensate for a decrease in temperature of a space near the edge of the target substrate due to the cooling ring.

Abstract: A plasma processing apparatus includes a vacuum evacuable processing chamber; a first electrode for mounting thereon a substrate to be processed in the processing chamber; a second electrode facing the first electrode in parallel in the processing chamber; and a processing gas supply unit for supplying a processing gas to a processing space between the first and the second electrode. The apparatus further includes a first high frequency power supply for applying a first high frequency power for generating a plasma of the processing gas to at least one of the first and the second electrode; and a cavity plasma generation unit, having a cavity formed in one of the first and the second electrode, for generating a plasma of a discharging gas in the cavity.

Abstract: A parallel resonance frequency can be adjusted in order to stably and securely block different high frequency noises flowing into a line such as a power feed line or a signal line from electric members including a high frequency electrode within a processing chamber. A filter 102(1) coaxially accommodates a coil 104(1) within a cylindrical outer conductor 110, and a ring member 122 is coaxially installed between the coil 104(1) and the outer conductor 110. The ring-shaped member 122 may be a plate body of a circular ring shape on a plane orthogonal to an axial direction of the outer conductor 110 and made of a conductor such as cupper or aluminum and electrically connected with the outer conductor 110 while electrically insulated from the coil 104(1).

Abstract: An apparatus includes an upper electrode and a lower electrode for supporting a wafer disposed opposite each other within a process chamber. A first RF power supply configured to apply a first RF power having a relatively higher frequency, and a second RF power supply configured to apply a second RF power having a relatively lower frequency is connected to the lower electrode. A variable DC power supply is connected to the upper electrode. A process gas is supplied into the process chamber to generate plasma of the process gas so as to perform plasma etching.

Abstract: A plasma processing apparatus includes a processing chamber including a dielectric window; a coil shaped RF antenna provided outside the dielectric window; a substrate supporting unit, provided in the processing chamber, for mounting thereon a target substrate to be processed; a processing gas supply unit for supplying a desired processing gas to the processing chamber to perform a desired plasma process on the target substrate; and an RF power supply unit for supplying an RF power to the RF antenna to generate a plasma of the processing gas by an inductive coupling in the processing chamber. The apparatus further includes a floating coil electrically floated and arranged at a position outside the processing chamber where the floating coil is to be coupled with the RF antenna by an electromagnetic induction; and a capacitor provided in a loop of the floating coil.

Abstract: A plasma processing apparatus includes: a processing chamber including a dielectric window; a coil-shaped RF antenna, provided outside the dielectric window; a substrate supporting unit, provided in the chamber, for mounting thereon a target substrate; a processing gas supply unit for supplying a processing gas to the chamber; and an RF power supply unit for supplying an RF power to the RF antenna to generate a plasma of the processing gas by an inductive coupling in the chamber. The apparatus further includes a correction coil, provided at a position outside the chamber where the correction coil is to be coupled with the RF antenna by an electromagnetic induction, for controlling a plasma density distribution in the chamber; and an antenna-coil distance control unit for controlling a distance between the RF antenna and the correction coil while supporting the correction coil substantially in parallel with the RF antenna.

Abstract: A plasma processing apparatus includes a processing chamber, a part of which is formed of a dielectric window; a substrate supporting unit, provided in the processing chamber, for mounting a target substrate; a processing gas supply unit for supplying a processing gas to the processing chamber to perform a plasma process on the target substrate; an RF antenna, provided outside the dielectric window, for generating a plasma from the processing gas by an inductive coupling in the processing chamber; and an RF power supply unit for supplying an RF power to the RF antenna. The RF antenna includes a single-wound or multi-wound coil conductor having a cutout portion in a coil circling direction; and a pair of RF power lines from the RF power supply unit are respectively connected to a pair of coil end portions of the coil conductor that are opposite to each other via the cutout portion.

Abstract: A plasma processing apparatus includes a processing chamber including a dielectric window; a coil-shaped RF antenna, provided outside the dielectric window; a substrate supporting unit provided in the processing chamber; a processing gas supply unit; an RF power supply unit for supplying an RF power to the RF antenna to generate a plasma of the processing gas by an inductive coupling in the processing chamber, the RF power having an appropriate frequency for RF discharge of the processing gas; a correction coil, provided at a position outside the processing chamber where the correction coil is to be coupled with the RF antenna by an electromagnetic induction, for controlling a plasma density distribution on the substrate in the processing chamber; a switching device provided in a loop of the correction coil; and a switching control unit for on-off controlling the switching device at a desired duty ratio by pulse width modulation.

Abstract: A plasma processing apparatus includes: an evacuable processing chamber including a dielectric window; a substrate supporting unit, provided in the processing chamber, for mounting thereon a target substrate; a processing gas supply unit for supplying a desired processing gas to the processing chamber to perform a plasma process on the target substrate; a first RF antenna, provided on the dielectric window, for generating a plasma by an inductive coupling in the processing chamber; and a first RF power supply unit for supplying an RF power to the first RF antenna. The first RF antenna includes a primary coil provided on or above the dielectric window and electrically connected to the first RF power supply unit; and a secondary coil provided such that the coils are coupled with each other by an electromagnetic induction therebetween while being arranged closer to a bottom surface of the dielectric window than the primary coil.

Abstract: A measuring system measuring an impedance of an object to be measured, including an impedance measuring instrument; a casing formed of a grounded conductor and capable of locating the object to be measured therein; and a radially-shaped electrode connected to the impedance measuring instrument and capable of being connected to the object to be measured.

Abstract: In a plasma processing apparatus in which a radio-frequency power from a radio-frequency power source is supplied to an electrode disposed in a process vessel, to thereby generate, in the process vessel, plasma with which a substrate is processed, a chemical component emitting member which is caused to emit a chemical component necessary for processing the substrate into the process vessel by entrance of ions in the plasma generated in the process vessel is provided in the process vessel in an exposed state, and an impedance varying circuit varying impedance on the chemical component emitting member side of the plasma generated in the process vessel to frequency of the radio-frequency power source is connected to the chemical component emitting member.

Abstract: A plasma processing apparatus includes a vacuum evacuable processing chamber; a lower electrode for mounting a target substrate in the processing chamber; a focus ring attached to the lower electrode to cover at least a portion of a peripheral portion of the lower electrode; an upper electrode disposed to face the lower electrode in parallel in the processing chamber; a processing gas supply unit for supplying a processing gas to a processing space; and a radio frequency (RF) power supply for outputting an RF power. Further, the plasma processing apparatus includes a plasma generating RF power supply section for supplying the RF power to a first load for generating a plasma of the processing gas; and a focus ring heating RF power supply section for supplying the RF power to a second load for heating the focus ring.

Abstract: Uniformity of plasma density distribution and process characteristics is improved by greatly improving performance and the degree of freedom for controlling the plasma density distribution. A capacitively coupled plasma processing apparatus includes a plasma density distribution controller, installed in a chamber lower room, for controlling plasma density distribution on a susceptor. The plasma density distribution controller includes a conductive plate (first conductor) which is placed under a rear surface of the susceptor at a certain position to face the susceptor and a conductive rod (second conductor) which supports the conductive plate upward and is electrically grounded. An upper end (first connecting portion) of the conductive rod is fixed to a certain portion of a bottom surface of the conductive plate, and a lower end (second connecting portion) of the conductive rod is fixed to or is in contact with a bottom wall of a chamber.

Abstract: In a plasma processing apparatus in which a radio-frequency power from a radio-frequency power source is supplied to at least one of an upper electrode and a lower electrode disposed to vertically face each other in a process vessel, to thereby generate, in the process vessel, plasma with which a substrate is processed, a chemical component emitting member which is caused to emit a chemical component necessary for processing the substrate into the process vessel by entrance of ions in the plasma generated in the process vessel is provided in the process vessel in an exposed state, and an impedance varying circuit varying impedance on the chemical component emitting member side of the plasma generated in the process vessel to frequency of the radio-frequency power source is connected to the chemical component emitting member.