A charged particle inspection system may include a shielding plate having an aperture or more than one aperture, for example, to permit additional inspection by an additional instrument requiring a line of sight to the area of interest. A field shaping element, such as a window element or a raised rim, is placed at the aperture to prevent or reduce a component of an electric field.

The invention relates to charged particle beam generator comprising a charged particle source for generating a charged particle beam, a collimator system comprising a collimator structure with a plurality of collimator electrodes for collimating the charged particle beam, a beam source vacuum chamber comprising the charged particle source, and a generator vacuum chamber comprising the collimator structure and the beam source vacuum chamber within a vacuum, wherein the collimator system is positioned outside the beam source vacuum chamber. Each of the beam source vacuum chamber and the generator vacuum chamber may be provided with a vacuum pump.

Apparatus and methods for generating a flow of radicals are provided. An ion blocker is positioned a distance from a faceplate of a remote plasma source. The ion blocker has openings to allow the plasma to flow through. The ion blocker is polarized relative to a showerhead positioned on an opposite side of the ion blocker so that there are substantially no plasma gas ions passing through the showerhead.

A particle beam system for examining and processing an object includes an electron beam column and an ion beam column with a common work region, in which an object may be disposed and in which a principal axis of the electron beam column and a principal axis of the ion beam column meet at a coincidence point. The particle beam system further includes a shielding electrode that is disposable between an exit opening of the ion beam column and the coincidence point. The shielding electrode is able to be disposed closer to the coincidence point than the electron beam column.

An input lens is provided which has a large acceptance solid angle for electrons. The input lens is for use in an electron spectrometer and disposed between an electron source producing electrons and an electron analyzer in the electron spectrometer. The input lens has a reference electrode at a reference potential, a slit, first through nth electrodes, where n is an integer equal to or greater than three, arranged between the reference electrode and the slit, and a second mesh attached to the first electrode. The first through nth electrodes are arranged in this order along an optical axis. The second mesh is at a potential higher than the reference potential.

Described herein is a technique capable of suppressing sputtering on an inner peripheral surface of a process vessel when a process gas is plasma-excited in the process vessel. According to one aspect thereof, a substrate processing apparatus includes: a process vessel accommodating a process chamber where a process gas is excited into plasma; a gas supplier supplying the process gas into the process chamber; a coil wound around an outer peripheral surface of the process vessel and spaced apart therefrom, wherein a high frequency power is supplied to the coil; and an electrostatic shield disposed between the outer peripheral surface and the coil, wherein the electrostatic shield includes: a partition extending in a circumferential direction to partition between a part of the coil and the outer peripheral surface; and an opening extending in the circumferential direction and opened between another part of the coil and the outer peripheral surface.

A charged particle beam device that can improve machining position precision in section processing using a shielding plate is provided. The invention is directed to a charged particle beam device including: an ion source (101); a sample stand (106) on which a sample (107) is mounted; a shielding plate (108) placed so that a portion of the sample (107) is exposed when seen from the ion source (101); and tilt units (123, 124) that tilt the sample (107) and the shielding plate (108) relative to the irradiation direction of an ion beam (102) from the ion source (101) to the sample (107).

There is provided an ion milling apparatus and sample holder permitting one to observe a sample, which has been milled, with an electron microscope without transferring the sample to a different holding member. The ion milling apparatus has an ion source, a sample holder, and a sample stage. The sample holder includes: a holder body having a sample holding portion for holding the sample; and a cover member detachably mounted to the holder body and hermetically sealing the sample held on the sample holding portion. The holder body has a shield plate and a field-correcting plate for correcting electric fields around the sample held on the sample holding portion.

Described herein is a technique capable of suppressing sputtering on an inner peripheral surface of a process vessel when a process gas is plasma-excited in the process vessel. According to one aspect thereof, a substrate processing apparatus includes: a process vessel accommodating a process chamber where a process gas is excited into plasma; a gas supplier supplying the process gas into the process chamber; a coil wound around an outer peripheral surface of the process vessel and spaced apart therefrom, wherein a high frequency power is supplied to the coil; and an electrostatic shield disposed between the outer peripheral surface and the coil, wherein the electrostatic shield includes: a partition extending in a circumferential direction to partition between a part of the coil and the outer peripheral surface; and an opening extending in the circumferential direction and opened between another part of the coil and the outer peripheral surface.

Disclosed herein is an apparatus comprising: a first electrically conductive layer; a second electrically conductive layer; a plurality of optics element s between the first electrically conductive layer and the second electrically conductive layer, wherein the plurality of optics elements are configured to influence a plurality of beams of charged particles; a third electrically conductive layer between the first electrically conductive layer and the second electrically conductive layer; and an electrically insulating layer physically connected to the optics elements, wherein the electrically insulating layer is configured to electrically insulate the optics elements from the first electrically conductive layer, and the second electrically conductive layer.