Abstract: A shower plate is disposed in a processing chamber in a plasma processing apparatus, and plasma excitation gas is released into the processing chamber so as to generate plasma. A ceramic member having a plurality of gas release holes having a diameter of 20 ?m to 70 ?m, and/or a porous gas-communicating body having pores having a maximum diameter of not more than 75 ?m communicating in the gas-communicating direction are sintered and bonded integrally with the inside of each of a plurality of vertical holes which act as release paths for the plasma excitation gas.

Abstract: This microwave plasma processing apparatus has, as a gas introduction mechanism for introducing a working gas inside a chamber (10), electrical discharge prevention members (96(1) to 96(8)), each of which is provided to a plurality of dielectric window gas passages (94(1) to (94(8)) through which a dielectric window (54) passes. Each electrical discharge prevention member (96(n)), a portion (114) of which protrudes only a height h, which is greater than or equal to a predetermined distance H, upward from the rear surface of a dielectric window (52) on the inlet side, passes through an opening (54a) of a slot plate (54), and inserts into a branched gas supply path (92(n)) of a gas branch part (90). The gas branch part (90), spring coils (116) and the slot plate (54), which surround the protruding portion (114) of each electrical discharge prevention member (96(n)), constitute an enclosing conductor (118).

Abstract: A plasma processing apparatus includes a plasma generating device configured to generate a plasma within a processing vessel by using a high frequency wave generated by a microwave generator 41 including a magnetron 42 configured to generate the high frequency wave; detectors 54a and 54b configured to measure a power of a traveling wave that propagates to a load side and a power of a reflected wave reflected from the load side, respectively; and a voltage control circuit 53a configured to control a voltage supplied to the magnetron 42 by a power supply 43. Further, the voltage control circuit 53a includes a load control device configured to supply, to the magnetron 42, a voltage corresponding to a power calculated by adding a power calculated based on the power of the reflected wave measured by the detector 54b to the power of the traveling wave measured by the detector 54a.

Abstract: A plasma processing device including a stage for holding a substrate, a processing vessel, a first supply unit, a masking portion, a dielectric member, a microwave introduction unit, and a second supply unit. The first supply unit supplies a first process gas for layer deposition to the processing space. The masking portion is electrically conductive and has a first surface facing the processing space, a second surface at an opposite side, and one or more through holes extending from the first surface to the second surface. The dielectric member is in contact with the second surface of the masking portion, and is formed with one or more cavities connected to the one or more through holes. The microwave introduction unit introduces microwaves to the dielectric member. The second supply unit supplies a second process gas for plasma processing into the cavities of the dielectric member.

Abstract: A manufacturing method of a top plate hermetically attached to an upper opening of a tubular shaped container body for forming a processing container of a plasma processing apparatus is provided. The manufacturing method includes the steps of; preparing a top plate body comprised of a dielectric body for transmitting an electromagnetic wave, and having a gas ejection hole for ejecting a gas into the processing container; forming a discharge prevention member having a discharge prevention member body comprised of a dielectric body having a permeability, and a dense member comprised of a dielectric body without a permeability covering at least a side face of the discharge prevention member body; and attaching the discharge prevention member in the gas ejection hole of the top plate body.

Abstract: A method of cleaning a plasma processing apparatus for processing a target in a process container, which is vacuum-evacuatable, using plasma, includes performing a first cleaning process by supplying a cleaning gas into the process container to generate plasma and maintaining the pressure in the process container at a first pressure, and performing a second cleaning process by supplying a cleaning gas into the process container to generate plasma and maintaining the pressure in the process container at a second pressure that is higher than the first pressure. Accordingly, the plasma processing apparatus can be efficiently and rapidly cleaned without damaging at least one of the group consisting of inner surfaces of the process container and members in the process container.

Abstract: The present invention provides a plasma processing unit comprising: a processing vessel having an opening on a ceiling side thereof, and capable of creating a vacuum therein; a stage disposed in the processing vessel, for placing thereon an object to be processed; a top plate made of a dielectric, the top plate being hermetically fitted in the opening and allowing a microwave to pass therethrough; a planar antenna member disposed on the top plate, the planar antenna member being provided with a plurality of microwave radiating holes for radiating a microwave for plasma generation toward an inside of the processing vessel; a slow-wave member disposed on the planar antenna member, for shortening a wavelength of a microwave; and a microwave interference restraining part disposed on a lower surface of the top plate, the microwave interference restraining part separating the lower surface into a plurality of concentric zones and restraining a microwave interference between the zones.

Abstract: Occurrence of a back-flow of plasma or ignition of gas for plasma excitation in a longitudinal hole portion can be prevented more completely, and a shower plate in which efficient plasma excitation is possible is provided. In shower plate 105, which is arranged in processing chamber 102 of a plasma processing apparatus and discharges gas for plasma excitation into processing chamber, porous-gas passing body 114 having a pore that communicates in the gas flow direction is fixed onto longitudinal hole 112 used as a discharging path of gas for plasma excitation. The pore diameter of a narrow path in a gas flowing path formed of a pore, which communicates to porous-gas passing body 114, is 10 ?m or lower.

Abstract: An antenna, a dielectric window, a plasma processing apparatus and a plasma processing method are capable of improving uniformity of a substrate surface processing amount in the surface of the substrate. The antenna includes the dielectric window 16; and a slot plate 20, provided on one side of the dielectric window 16, having a plurality of slots 133. The dielectric window 16 has a flat surface 146 surrounded by a ring-shaped first recess; and a plurality of second recesses 153 formed on the flat surface 146 so as to surround a center of the flat surface 146. Here, the flat surface 146 is formed on the other side of the dielectric window 16. When viewed from a thickness direction of the slot plate, a center of each second recess 153 is located within each slot 133 of the slot plate.

Abstract: A ceiling plate provided at a ceiling portion of a process chamber that may be evacuated to a vacuum is disclosed. The ceiling plate allows microwaves emitted from a slot of a planar antenna member provided along with the ceiling plate to pass through the ceiling plate into the process chamber, and includes plural concave portions provided along a circle on a surface of the ceiling plate, the surface facing toward an inside of the process chamber.

Abstract: A plasma processing apparatus includes a processing chamber, a stage, a dielectric member, a microwave introduction device, an injector, and an electric field shield. The processing chamber has a processing space therein. The stage is provided within the processing chamber. The dielectric member has a through hole and is provided to face the stage. The microwave introduction device is configured to introduce microwave into the processing space via the dielectric member. The injector has at least one through hole and is made of a dielectric material, e.g., a bulk dielectric material. The injector is provided within the dielectric member. The injector and the through hole of the dielectric member form a path for supplying a processing gas into the processing space. The electric field shield encloses the injector.

Abstract: In the plasma processing apparatus 1, microwaves supplied from a coaxial waveguide 30 are introduced into a processing container 2 via a wavelength-shortening plate 25, a process gas is plasmatized in the processing container 2, and a substrate W is processed using the plasma. In the plasma processing apparatus 1, a dielectric member 45 is disposed at a connecting area between the coaxial waveguide 30 and the wavelength-shortening plate 25. Inside an outer conductor 32 of the coaxial waveguide 30, the dielectric member 45 is disposed to surround a part of a circumference of an inner conductor 31 of the coaxial waveguide 30, and is disposed at any position around the circumference of the inner conductor 31.

Abstract: In a plasma processing apparatus that processes a wafer in a process vessel by plasma generated by the supply of a microwave, a transmissive window has, in a center area of its lower surface, a hanging portion made of the same material as a material of the transmissive window. Between an outer peripheral surface of the hanging portion and a sidewall inner surface continuing from a support part, a gap is formed, the gap having a gap length of 0.5 to 10 mm, more preferably 0.5 to 5 mm. The generation of a strong electric field and plasma at a contact point is inhibited and an amount of sputtered particles, radicals, or the like reaching the wafer is also reduced.

Abstract: The shower plate is arranged to seal an upper opening of a process container that is configured by a chamber, a spacer, and an upper plate. A plasma excitation gas is spurted into the chamber through the opening portions of the shower plate. Microwaves are supplied to a slot antenna arranged outside the shower plate, thereby generating plasma. Atmospheric air in a first gap between the inner wall of the spacer and the outer circumferential surface of the shower plate and a second gap between a radiation surface of the slot antenna and the dielectric cover plate is sucked by a gas suction unit through gas exhaust holes. The toxic gas is purified by a gas purification unit. Thus, the toxic gas is prevented from leaking out of the plasma processing apparatus even when the shower plate is broken.

Abstract: A microwave supply unit 20 of a plasma processing apparatus 11 includes a stub member 51 configured to be extensible from the outer conductor 33 toward the inner conductor 32. The stub member 51 serves as a distance varying device for varying a distance in the radial direction between a part of the outer surface 36 of the inner conductor 32 and a facing member facing the part of the outer surface of the inner conductor 32 in the radial direction, i.e., the cooling plate protrusion 47. The stub member 51 includes a rod-shaped member 52 supported at the outer conductor 33 and configured to be extended in the radial direction; and a screw 53 as a moving distance adjusting member for adjusting a moving distance of the rod-shaped member 52 in the radial direction.

Abstract: A coolant flow path for cooling a dielectric window of a side wall of a processing container of the plasma processing apparatus is provided. A coolant flows in a liquid or gaseous state in the coolant flow path without phase transition. At least a portion of the coolant flow path extending in a circumferential direction of the side wall has a cross-sectional area decreased toward downstream from upstream.

Abstract: A gate valve corresponding to the sealing structure seals an opening of a plasma generation chamber and includes a valve body, a valve stem, and ring-shaped first and second sealing members that seal a gap between the valve body and the plasma generation chamber. The first ring-shaped sealing member is on the side of the plasma generation chamber and is exposed to a plasma atmosphere. The first and second ring-shaped sealing members do not contact each other, that is, a gap is formed therebetween. A plurality of gas grooves are arranged in the length direction of the first ring-shaped sealing member. The gas grooves are formed by cutting the valve body in a direction almost perpendicular to the length direction of the first ring-shaped sealing member, and the gap is in communication with the plasma generation chamber via the gas grooves. A gas injection passage 14 for injecting a gas into the gap is formed in the wall of the plasma generation chamber.

Abstract: A plasma processing apparatus includes a chamber for carrying out plasma processing inside, a top plate made of a dielectric material for sealing the upper side of this chamber, and an antenna section that serves as a high frequency supply for supplying high frequency waves into the chamber via this top plate. The top plate is provided with reflecting members inside thereof. The sidewalls of the reflecting members work as wave reflector for reflecting high frequency waves that propagate inside the top plate in the radius direction. Alternatively, no reflecting members may be provided in a manner in which the sidewalls of a recess of the top plate serve as a wave reflector means.

Abstract: Resonance can be surely provided under any plasma condition in such a manner that an antenna (3) is arranged in an opening of an upper part of a chamber (1) to produce an electromagnetic field generated by a microwave, a top plate (4) for sealing the opening of the chamber (1) is provided under the antenna (3), a ring-shaped ridge (41) is provided on a lower surface of the top plate (4) such that a thickness thereof in a diameter direction is tapered so as to be varied sequentially. Thus, only one kind of top plate has the same effect as a top plate having various thicknesses, so that absorption efficiency to the plasma can be considerably improved and the plasma can be generated stably over a range from a high pressure to a low pressure.

Abstract: A plasma generation chamber of a plasma processing apparatus is closed by a top plate 3. The top plate 3 has recesses 3A on its surface facing the plasma generation chamber and a central recess 3B on an opposite surface. The top plate 3 is coupled to an antenna thereon. If a microwave is supplied to the antenna, the microwave is radiated through slots of the antenna. The microwave is propagated through the top plate 3 such that the microwave has a plane of polarization and the microwave forms a circularly polarized wave as a whole. Here, resonance absorption of the microwave occurs at a side surface of recesses 3A and the microwave is propagated within the recesses 3A in a single mode. Strong plasma can be generated within each of the recesses 3A, so that a stable plasma mode can be generated in the top plate 3.