Embodiments disclosed herein relate to a substrate processing chamber component assembly with plasma resistant seal. In one embodiment, the semiconductor processing chamber component assembly includes a first semiconductor processing chamber component, a second semiconductor processing component, and a sealing member. The sealing member has a body formed substantially from polytetrafluoroethylene (PTFE). The sealing member provides a seal between the first and second semiconductor processing chamber components. The body includes a first surface, a second surface, a first sealing surface, and a second sealing surface. The first surface is configured for exposure to a plasma processing region. The second surface is opposite the first surface. The first sealing surface and the second sealing surface extend between the first surface and the second surface. The first sealing surface contacts the first semiconductor processing chamber component. The second sealing surface contacts the second semiconductor processing chamber component.

A charged particle beam device, comprising a charged particle beam source situated in a first-pressure environment, a sample support operative to support a sample situated in a second-pressure environment, the second-pressure environment having a higher pressure than the first-pressure environment, and a membrane assembly separating the first-pressure environment from the second-pressure environment, the membrane assembly comprising a pressure-sealing membrane being substantially transparent to a charged particle beam from the charged particle beam source, a supporting membrane layer being formed with a cornerless aperture, the pressure-sealing membrane being bonded to the supporting membrane layer, and a holding frame being formed with a second aperture larger than and overlying the cornerless aperture. The charged particle beam device may further comprise an electron-detecting subassembly, the electron-detecting subassembly comprising at least one metal line defining a shape, for detection of electrons resulting from an interaction of the charged particle beam and the sample.

A corrosion-resistant component configured for use with a semiconductor processing reactor, the corrosion-resistant component comprising: a) a ceramic insulating substrate; and, b) a white corrosion-resistant non-porous outer layer associated with the ceramic insulating substrate, the white corrosion-resistant non-porous outer layer having a thickness of at least 50 m, a porosity of at most 1%, and a composition comprising at least 15% by weight of a rare earth compound based on total weight of the corrosion-resistant non-porous layer; and, c) an L* value of at least 90 as measured on a planar surface of the white corrosion-resistant non-porous outer layer. Methods of making are also disclosed.

[Problem]

A technique capable of preventing gas containing a contaminant from flowing into a container and preventing inert gas flowing out of the container is provided.

[Solution]

An optical apparatus 100 includes a light irradiation device 1 capable of emitting light 3, a plurality of container components 13, 21, and 31, a gas supply port 22, and a gas suction port 32. A purge space 20 to which inert gas is supplied, a gas suction space 30 from which gas present is suctioned, and a space outside apparatus 80 are separated from each other by the plurality of container components 13, 21, and 31. The purge space 20 is used as the optical path of the light 3. An optical element 4b is disposed in the purge space 20. By supplying inert gas from a gas supply port 22 into the purge space 20 and suctioning gas present in the gas suction space 30 from the gas suction port 32, atmospheric pressure in the gas suction space 30 can be controlled to be lower than atmospheric pressure in the purge space 20 and atmospheric pressure in the space outside apparatus 80.

A charged particle beam device capable of observing a sample in an air atmosphere or gas atmosphere has a thin film for separating the atmospheric pressure space from the decompressed space. A vacuum evacuation pump evacuates a first housing; and a detector detects a charged particle beam (obtained by irradiation of the sample) in the first housing. A thin film is provided to separate the inside of the first housing and the inside of a second housing at least along part of the interface between the first and second housings. An opening part is formed in the thin film so that its opening area on a charged particle irradiation unit's side is larger than its opening area on the sample side; and the thin film which covers the sample side of the opening part transmits or allows through the primary charged particle beam and the charged particle beam.

A corrosion-resistant component configured for use with a semiconductor processing reactor, the corrosion-resistant component comprising: a) a ceramic insulating substrate; and, b) a corrosion-resistant non-porous layer associated with the ceramic insulating substrate, the corrosion-resistant non-porous layer having a composition comprising at least 15% by weight of a rare earth compound based on total weight of the corrosion-resistant non-porous layer; and, the corrosion-resistant non-porous layer characterized by a microstructure substantially devoid of microcracks and fissures, and having an average grain size of at least about 100 nm and at most about 100 m. Assemblies including corrosion-resistant components and methods of making are also disclosed.

An inspection apparatus capable of facilitating reduction in cost of the apparatus is provided. The inspection apparatus includes: beam generation means for generating any of charged particles and electromagnetic waves as a beam; a primary optical system that guides the beam into an inspection object held on a movable stage in a working chamber and irradiates the inspection object with the beam; a secondary optical system that detects secondary charged particles occurring from the inspection object; and an image processing system that forms an image on the basis of the detected secondary charged particles. The inspection apparatus further includes: a linear motor that drives the movable stage; and a Helmholtz coil that causes a magnetic field for canceling a magnetic field caused by the linear motor when the movable stage is driven.

An apparatus that may be used to allow the rotation of a component that passes through a wall of a vacuum chamber is disclosed. The apparatus includes a rotatable shaft through which the component passes. The rotatable shaft is held in place using a holder, which retains a portion of the rotatable shaft. In some embodiments, the holder is affixed to a plate, which is then affixed to the chamber wall. The plate has an opening which is aligned to the opening in the chamber wall. A portion of the rotatable shaft passes through the opening in the plate and vacuum seals are disposed between the rotatable shaft and the plate. This apparatus may be used to allow use of rotatable components in an ion implanter.

Disclosed herein is a seal assembly for a substrate processing chamber and a component assembly containing the seal assembly. The seal assembly includes a ring-shaped seal member; a holder disposed radially inward of the ring-shaped seal member; and a retaining mechanism coupling the ring-shaped seal member with the holder. The component assembly includes a first component coupled with a second component via a bonding layer; a groove formed by the first component, the second component, and the bonding layer; and the seal assembly disposed in the groove.

A gas reservoir that receives a precursor has a gas-receiving unit which is arranged in a first receiving unit of a basic body and a sliding unit which is arranged movably in a second receiving unit of the basic body. The gas-receiving unit has a movable closure unit for opening or closing a gas outlet opening of the gas-receiving unit. In a first position of the sliding unit, a first opening of a sliding-unit line device is fluidically connected to a first basic body opening and a second opening of the sliding-unit line device is fluidically connected to a second basic body opening. In the second position of the sliding unit, the first opening is arranged at an inner wall of the second receiving unit and the second opening is arranged at the movable closure unit.