Abstract: A plasma processing apparatus includes: a processing container; an electrode that places a substrate thereon within the processing container; a plasma generation source that supplies plasma into the processing container; a bias power supply that supplies bias power to the electrode; a part exposed to the plasma in the processing container; a DC power supply that supplies a DC voltage to the part; a controller that executes a process including a first control procedure in which a first state in which the DC voltage has a first voltage value and a second state in which the DC voltage has a second voltage value higher than the first voltage value are periodically repeated, and the first voltage value is applied in a partial period in each cycle of a potential of the electrode, and the second voltage value is applied such that the first state and the second state are continuous.

Abstract: A substrate processing apparatus includes a processing vessel; a placing table provided within the processing vessel and configured to place a substrate thereon; and a component disposed between the processing vessel and the placing table, the component constituting an anode. The component has a flow path through which a heat exchange medium flows.

Abstract: In an exemplary embodiment, an upper electrode is disposed in a processing chamber to face a susceptor and provided with a plate-like member and an electrode part. In an exemplary embodiment, the plate-like member is formed with a gas distribution hole that distributes a processing gas used for a plasma processing. The electrode part is formed in a film shape by thermally spraying silicon onto a surface of the plate-like member where an outlet of the gas distribution hole is formed.

Abstract: A substrate processing apparatus includes: a first processing chamber; a second processing chamber; a transfer chamber; a frame structure; and an elevating part. Each of the first and the second processing chamber has a main body part and a lid part. The transfer chamber is connected to the first and the second processing chamber and accommodates a transfer unit for transferring the substrate. The frame structure has a pair of column parts and a beam part supported at top portions of the column parts. The elevating part is coupled to the beam part to be moved in a horizontal direction and moves the lid part in the vertical direction. The beam part extends above the first and the second processing chamber and the transfer chamber.

Abstract: An upper electrode structure includes a first plate, a second plate and an electrostatic attraction unit. The first plate has a first region, a second region and a third region which are concentrically arranged. Each of the regions is provided with a multiple number of gas discharge openings. The electrostatic attraction unit is provided between the first plate and the second plate and is configured to attract the first plate. The electrostatic attraction unit is equipped with a first to third heaters for the first to third regions. The electrostatic attraction unit and the second plate provide a first supply path, a second supply path and a third supply path through which gases are supplied into the first to third regions, respectively. A first gas diffusion space, a second gas diffusion space and a third gas diffusion space are formed in the electrostatic attraction unit.

Abstract: In an exemplary embodiment, an upper electrode is disposed in a processing chamber to face a susceptor and provided with a plate-like member and an electrode part. In an exemplary embodiment, the plate-like member is formed with a gas distribution hole that distributes a processing gas used for a plasma processing. The electrode part is formed in a film shape by thermally spraying silicon onto a surface of the plate-like member where an outlet of the gas distribution hole is formed.

Abstract: A shower head assembly includes an electrode plate, and a laminate base that is constituted of ceramic sheets and provided to hold the electrode plate. The laminate base includes no bonding surface between the ceramic sheets. The laminate base includes a first gas diffusion space formed in its central area and a second gas diffusion space formed in its peripheral area. A first heater electrode layer is provided above the first gas diffusion space, and a second heater electrode layer is provided above the second gas diffusion space. A first coolant passage is formed above the first gas diffusion space, and a second coolant passage is formed above the second gas diffusion space. A first gas supply passage is connected to the first gas diffusion space, and a second gas supply passage is connected to the second gas diffusion space.

Abstract: A substrate processing apparatus includes: a first processing chamber; a second processing chamber; a transfer chamber; a frame structure; and an elevating part. Each of the first and the second processing chamber has a main body part and a lid part. The transfer chamber is connected to the first and the second processing chamber and accommodates a transfer unit for transferring the substrate. The frame structure has a pair of column parts and a beam part supported at top portions of the column parts. The elevating part is coupled to the beam part to be moved in a horizontal direction and moves the lid part in the vertical direction. The beam part extends above the first and the second processing chamber and the transfer chamber.

Abstract: A plasma etching method by using a plasma etching apparatus having a depressurizable processing chamber; a lower electrode for mounting thereon a substrate to be processed in the processing chamber; an upper electrode facing the lower electrode in the processing chamber with a plasma generation region formed therebetween; a radio frequency power supply unit for applying a radio frequency power between the upper electrode and the lower electrode to thereby form a radio frequency electric field in the plasma generation region, the method comprising: supplying a first gas including etchant gas to an upper gas inlet to introduce the first gas through the upper electrode into the plasma generation region; and feeding a second gas including dilution gas to a side gas inlet to introduce the second gas through a sidewall of the processing chamber into the plasma generation region.

Abstract: A plasma processing method is arranged to supply a predetermined process gas into a plasma generation space in which a target substrate is placed, and turn the process gas into plasma. The substrate is subjected to a predetermined plasma process by this plasma. The spatial distribution of density of the plasma and the spatial distribution of density of radicals in the plasma are controlled independently of each other relative to the substrate by a facing portion opposite the substrate to form a predetermined process state over the entire target surface of the substrate.

Abstract: A plasma processing method is arranged to supply a predetermined process gas into a plasma generation space in which a target substrate is placed, and turn the process gas into plasma. The substrate is subjected to a predetermined plasma process by this plasma. The spatial distribution of density of the plasma and the spatial distribution of density of radicals in the plasma are controlled independently of each other relative to the substrate by a facing portion opposite the substrate to form a predetermined process state over the entire target surface of the substrate.

Abstract: A plasma etching method by using a plasma etching apparatus having a depressurizable processing chamber; a lower electrode for mounting thereon a substrate to be processed in the processing chamber; an upper electrode facing the lower electrode in the processing chamber with a plasma generation region formed therebetween; a radio frequency power supply unit for applying a radio frequency power between the upper electrode and the lower electrode to thereby form a radio frequency electric field in the plasma generation region, the method comprising: supplying a first gas including etchant gas to an upper gas inlet to introduce the first gas through the upper electrode into the plasma generation region; and feeding a second gas including dilution gas to a side gas inlet to introduce the second gas through a sidewall of the processing chamber into the plasma generation region.

Abstract: A plasma processing method is arranged to supply a predetermined process gas into a plasma generation space in which a target substrate is placed, and turn the process gas into plasma. The substrate is subjected to a predetermined plasma process by this plasma. The spatial distribution of density of the plasma and the spatial distribution of density of radicals in the plasma are controlled independently of each other relative to the substrate by a facing portion opposite the substrate to form a predetermined process state over the entire target surface of the substrate.

Abstract: A plasma processing apparatus includes a process container configured to have a vacuum atmosphere therein. An upper electrode is disposed to face a target substrate placed within the process container. An electric feeder includes a first cylindrical conductive member continuously connected to the upper electrode in an annular direction. The electric feeder is configured to supply a first RF output from a first RF power supply to the upper electrode.

Abstract: A plasma processing apparatus includes a process container configured to have a vacuum atmosphere therein. A first upper electrode is disposed to have a ring shape and to face a target substrate placed within the process container. A second upper electrode is disposed radially inside the first upper electrode and electrically insulated therefrom. A first electric feeder is configured to supply a first RF output from a first RF power supply to the first upper electrode at a first power value. A second electric feeder branches from the first electric feeder and is configured to supply the first RF output from the first RF power supply to the second upper electrode at a second power value smaller than the first power value.

Abstract: In order to improve a controllability of etching characteristics by way of precisely and freely controlling a flow or a density distribution of a processing gas introduced into a processing chamber, a plasma etching apparatus includes, as a gas inlet for introducing an etching gas into a plasma generation region PS in a chamber 10, an upper gas inlet (an upper central shower head 66a and an upper peripheral shower head 68a) for introducing a gas through an upper electrode 38; and a side gas inlet for introducing a gas through a sidewall of the chamber 10. The side gas inlet 104 has a side shower head 108 attached to the sidewall of the chamber 10.

Abstract: A plasma processing method is arranged to supply a predetermined process gas into a plasma generation space in which a target substrate is placed, and turn the process gas into plasma. The substrate is subjected to a predetermined plasma process by this plasma. The spatial distribution of density of the plasma and the spatial distribution of density of radicals in the plasma are controlled independently of each other relative to the substrate by a facing portion opposite the substrate to form a predetermined process state over the entire target surface of the substrate.

Abstract: A plasma processing apparatus includes a process container configured to have a vacuum atmosphere therein. A first upper electrode is disposed to have a ring shape and to face a target substrate placed within the process container. A second upper electrode is disposed radially inside the first upper electrode and electrically insulated therefrom. A first electric feeder is configured to supply a first RF output from a first RF power supply to the first upper electrode at a first power value. A second electric feeder branches from the first electric feeder and is configured to supply the first RF output from the first RF power supply to the second upper electrode at a second power value smaller than the first power value.

Abstract: A plasma processing apparatus includes a process container configured to have a vacuum atmosphere therein. An upper electrode is disposed to face a target substrate placed within the process container. An electric feeder includes a first cylindrical conductive member continuously connected to the upper electrode in an annular direction. The electric feeder is configured to supply a first RF output from a first RF power supply to the upper electrode.

Abstract: An apparatus for processing a substrate of the present invention comprises a holder holding a substrate, a supply pipe being supplied with a processing solution from a first end and supplying the processing solution to the substrate from a second end, a first temperature controller having a first temperature controlled water circulated inside which controls a first temperature around the second end of the supply pipe and a second temperature controller having a second temperature controlled water drained from the first temperature controller circulated inside, which controls a second temperature around the first end of the supply pipe. With such a configuration, the temperature controlled water used for controlling the temperature of the processing solution just before its application onto the substrate can be recycled for controlling the temperature of the processing solution just after being supplied to a supply pipe.