Abstract: A substrate processing method uses a substrate processing apparatus including a chamber for accommodating a substrate, a lower electrode to mount the substrate, a first RF power applying unit for applying an RF power for plasma generation into the chamber, and a second RF power applying unit for applying an RF power for bias to the lower electrode. The RF power for plasma generation is controlled to be intermittently changed by changing an output of the first RF power applying unit at a predetermined timing. If no plasma state or an afterglow state exists in the chamber by a control of the first RF power applying unit, an output of the second RF power applying unit is controlled to be in an OFF state or decreased below an output of the second RF power applying unit when the output of the first RF power applying unit is a set output.

Abstract: A plasma processing apparatus includes a processing chamber that plasma processes a target object therein, first and second electrodes that are provided in the processing chamber to face each other and have a processing space therebetween, and a high frequency power source that is connected to at least one of the first and second electrodes to supply high frequency power to the processing chamber. At least one of the first and second electrodes includes a base formed of a metal, a dielectric material provided at a central portion of a plasma side of the base, and a first resistor provided between the dielectric material and plasma, and formed of a metal with a predetermined pattern.

Abstract: A plasma processing apparatus includes a processing chamber in which a target object is processed by a plasma, a first and a second electrode that are provided in the processing chamber to face each other and have a processing space therebetween, and a high frequency power source that is connected to at least one of the first and the second electrode to supply a high frequency power to the processing chamber. And at least one of the first and the second electrode includes a base formed of a plate-shaped dielectric material and a resistor formed of a metal and provided between the base and the plasma.

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. An RF power supply is disposed to supply an RF power to the first or second 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. The target substrate is supported by a support member between the first and second electrodes such that a process target surface thereof faces the second electrode. A conductive functional surface is disposed in a surrounding region around the plasma generation region and grounded to be coupled with the plasma in a sense of DC to expand the plasma.

Abstract: A mounting table for use in a plasma processing apparatus, on which a substrate is mounted, includes: an inner conductive member connected to an ion attracting RF power supply; an outer conductive member connected to a plasma generating RF power supply, the outer conductive member surrounding the inner conductive member; and a partition member formed of a dielectric material, the partition member partitioning between the inner conductive member and the outer conductive member. Further, the mounting table includes an electrostatic chuck formed of a dielectric material and arranged between the substrate and the inner conductive member, and between the substrate and the outer conductive member; and a dielectric layer arranged between the electrostatic chuck and the inner conductive member to conceal the inner conductive member from the electrostatic chuck. The electrostatic chuck includes an electrode film that is connected to a high voltage DC power supply.

Abstract: There are provided a substrate processing apparatus and a substrate processing method realizing an effective reduction of a voltage change of a substrate on an electrode to reduce the variation of incident energy of ions entering the substrate. The substrate processing apparatus includes: a first electrode holding a substrate on a main surface of the first electrode; a second electrode facing the first electrode; a RF power source applying to the first electrode a RF voltage whose frequency is equal to or higher than 40 MHz; and a pulse voltage applying unit applying to the first electrode a pulse voltage decreasing in accordance with a lapse of time, by superimposing the pulse voltage on the RF voltage.

Abstract: A mounting table for use in a plasma processing apparatus, on which a substrate is mounted, includes: a conductive member connected to a high frequency power supply and a high frequency power supply; a dielectric layer embedded in a central portion on an upper surface of the conductive member; and an electrostatic chuck mounted on the dielectric layer. Further, the electrostatic chuck is connected to a high voltage DC power supply and includes an electrode film satisfying following conditions: ?/z?85 (where ?=(?v/(??f))1/2) and, a surface resistivity of the substrate>a surface resistivity of a central portion of the electrode film.

Abstract: A processing apparatus for performing a process on a surface of an object to be processed by applying a high frequency power to an electrode installed in an airtight processing chamber to convert a processing gas introduced therein into a plasma, includes a thermal transfer gas feed pathway for supplying a thermal transfer gas for controlling a temperature of the object to be processed to a minute space between the object to be processed and a holding unit installed on the electrode for attracting and holding the object to be processed through an inner portion of an insulating member disposed under the electrode. A portion of the thermal transfer gas feed pathway, which passes through the inner portion of the insulating member, is formed in a zigzag shape or a spiral shape with respect to a normal direction of a holding surface of the holding unit.

Abstract: A plasma processing apparatus for performing a plasma process on a target substrate includes a process container configured to accommodate the target substrate and to reduce pressure therein. A first electrode is disposed within the process container. A supply system is configured to supply a process gas into the process container. An electric field formation system is configured to form an RF electric field within the process container so as to generate plasma of the process gas. A number of protrusions are discretely disposed on a main surface of the first electrode and protrude toward a space where the plasma is generated.

Abstract: An electrostatic chuck device includes an electrostatic chuck section including a substrate and a power supply terminal for applying a DC voltage to an electrostatic-adsorption inner electrode; and a metal base section fixed to the other main surface of the electrostatic chuck section. Here, a concave portion is formed in the main surface of the metal base section facing the electrostatic chuck section and a dielectric plate is fixed to the concave portion. The dielectric plate and the electrostatic chuck section are adhesively bonded to each other with an insulating adhesive bonding layer interposed therebetween. The dielectric plate and the concave portion are adhesively bonded to each other with an insulating adhesive bonding layer interposed therebetween. The dielectric constant of the insulating adhesive bonding layer is smaller than that of any one of the dielectric plate and the substrate.

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 plasma processing apparatus includes a processing gas supplying unit for supplying a desired processing gas to a processing space between an upper electrode and a lower electrode which are disposed facing each other in an evacuable processing chamber. The plasma processing apparatus further includes a radio frequency (RF) power supply unit for applying an RF power to one of the lower and the upper electrode to generate plasma of the processing gas by RF discharge and an electrically conductive RF ground member which covers a periphery portion of the electrode to which the RF power is applied to receive RF power emitted outwardly in radial directions from the periphery portion of the electrode to which the RF power is applied and send the received RF power to a ground line.

Abstract: A plasma processing apparatus for performing a plasma process on a target substrate includes a process container configured to accommodate the target substrate and to reduce pressure therein. A first electrode is disposed within the process container. A supply system is configured to supply a process gas into the process container. An electric field formation system is configured to form an RF electric field within the process container so as to generate plasma of the process gas. A number of protrusions are discretely disposed on a main surface of the first electrode and protrude toward a space where the plasma is generated.

Abstract: The present invention provides an upper electrode used in an etching apparatus and the etching apparatus including the upper electrode, both of which can properly reduce intensity of electric field of plasma around a central portion of a substrate to be processed, thus enhancing in-plane uniformity of a plasma process. In this apparatus, a recess, serving as a space for allowing a dielectric to be injected therein, is provided around a central portion of the upper electrode. A dielectric supply passage configured for supplying the dielectric into the space and a dielectric discharge passage configured for discharging the dielectric from the space are connected with the space, respectively.

Abstract: A mounting stage for a plasma processing apparatus that can prevent degradation of an insulating film in a semiconductor device on a substrate. A conductor member is connected to a radio-frequency power source for producing plasma. A dielectric layer is buried in a central portion of an upper surface of the conductor member. An electrostatic chuck is mounted on the dielectric layer. The electrostatic chuck has an electrode film that satisfies the following condition: ?/z?85 where ?=(?v/(??f))1/2 where z is the thickness of the electrode film, ? is the skin depth of the electrode film with respect to radio-frequency electrical power supplied from the radio-frequency power source, f is the frequency of the radio-frequency electrical power, ? is the ratio of a circumference of a circle to its diameter, ? is the magnetic permeability of the electrode film, and ?v is the specific resistance of the electrode film.

Abstract: A substrate plasma processing apparatus includes a substrate holding electrode and a counter electrode which are arranged in a chamber, a high frequency generating device which applies a high frequency of 50 MHZ or higher to the substrate holding electrode, a DC negative pulse generating device which applies a DC negative pulse voltage in a manner of superimposing on the high frequency, and a controller controlling to cause intermittent application of the high frequency and cause intermittent application of the DC negative pulse voltage according to the timing of on or off of the high frequency.

Abstract: A substrate processing method that can eliminate unevenness in the distribution of plasma. The method is for a substrate processing apparatus that has a processing chamber in which a substrate is housed, a mounting stage that is disposed in the processing chamber and on which the substrate is mounted, and an electrode plate that is disposed in the processing chamber such as to face the mounting stage, the electrode plate being made of silicon and connected to a radio-frequency power source, and carries out plasma processing on the substrate. In the plasma processing, the temperature of the electrode plate is measured, and based on the measured temperature, the temperature of the electrode plate is maintained lower than a critical temperature at which the specific resistance value of the silicon starts changing.

Abstract: A plasma processing apparatus includes a first radio frequency (RF) power supply unit for applying a first RF power for generating a plasma from a processing gas to at least one of a first and a second electrode which are disposed facing each other in an evacuable processing chamber. The first RF power supply unit is controlled by a control unit so that a first phase at which the first RF power has a first amplitude for generating a plasma and a second phase at which the first RF power has a second amplitude for generating substantially no plasma are alternately repeated at predetermined intervals.

Abstract: [Object] To provide a stage for plasma processing apparatus, the stage being capable of improving uniformity of electric field strength in a plasma so as to enhance an in-plane uniformity of a plasma process to a substrate, and to provide a plasma processing apparatus provided with this stage. [Means for Solving the Problem] A stage 1 for a plasma processing apparatus 2 comprises: a conductive member 21 serving as an electrode for generating a plasma or the like; a dielectric layer 22 covering a center part of an upper surface of the conductive member, for making uniform a radiofrequency electric field applied to a plasma through a substrate to be processed (wafer W); and an electrostatic chuck laminated on the dielectric layer 22, the electric chuck having a plurality of electrode films embedded therein, the electrode films being separated apart from each other in a radial direction of the stage to allow passage of a radiofrequency.

Abstract: An electrostatic chuck device includes: an electrostatic chuck section including a substrate, which has a main surface serving as a mounting surface on which a plate-like sample is mounted and an electrostatic-adsorption inner electrode built therein, and a power supply terminal for applying a DC voltage to the electrostatic-adsorption inner electrode; and a metal base section that is fixed to the other main surface of the electrostatic chuck section so as to be incorporated into a body and that serves as a high frequency generating electrode. Here, the electrostatic-adsorption inner electrode has one or more electrode portions, and a resistance value of a distance between a point corresponding to a center axis of the substrate or a point closest to the center axis and a point most distant from the center axis among distances between two points in the electrode portion is in the range of 102? to 1010?.