An inspection tool includes a controller that is configured to generate a scan pattern for an electron beam to image areas of interest on the wafer. The scan pattern minimizes dwell time of the electron beam on the surface of the wafer between the areas of interest. At least one stage speed and at least one raster pattern can be selected based on the areas of interest. The controller sends instructions to electron beam optics to direct the electron beam at the areas of interest on the surface of the wafer using the scan pattern.

By irradiating a sample with an unfocused ion beam, processing accuracy of an ion milling device for processing a sample or reproducibility accuracy of a shape of a processed surface is improved. Therefore, the ion milling device includes a sample chamber, an ion source position adjustment mechanism provided at the sample chamber, an ion source attached to the sample chamber via the ion source position adjustment mechanism and configured to emit an ion beam, and a sample stage configured to rotate around a rotation center. When a direction in which the rotation center extends when an ion beam center of the ion beam matches the rotation center is set as a Z direction, and a plane perpendicular to the Z direction is set as an XY plane, the ion source position adjustment mechanism is capable of adjusting a position of the ion source on the XY plane and a position of the ion source in the Z direction.

Aspects of the disclosure relate to apparatus for the fabrication of waveguides. In one example, an angled ion source is utilized to project ions toward a substrate to form a waveguide which includes angled gratings. In another example, an angled electron beam source is utilized to project electrons toward a substrate to form a waveguide which includes angled gratings. Further aspects of the disclosure provide for methods of forming angled gratings on waveguides utilizing an angled ion beam source and an angled electron beam source.

A charged particle beam writing apparatus includes a circuitry to set, when a charged particle beam is deflected to move between plural small regions by a deflector, plural first mesh regions obtained by virtually dividing a chip region into regions by length and width sizes same as those of each of the plural small regions; determine whether a shot figure having been assigned exists in each of the plural first mesh regions; a circuitry to perform, for the plural first mesh regions, merging of two or more adjacent first mesh regions; a circuitry to measure, for each of plural second mesh regions each obtained by merging, the number of first mesh regions each having been determined that an assigned shot figure exists therein; and a circuitry to generate a map for each chip, where measured number of first mesh regions with the shot figure is defined as a map value.

A beam current density distribution adjustment device is provided. The device includes member pairs in a long side direction of a ribbon beam, the member pairs adjusting a beam current density distribution in the long side direction of the ribbon beam by using an electric field or a magnetic field, members of each of the member pairs being disposed with the ribbon beam in-between the members. Opposing surfaces of the member pairs adjacent to each other in the long side direction of the ribbon beam are partially not parallel to a traveling direction of the ribbon beam.

A mass analyzing electromagnet is provided. The mass analyzing electromagnet includes an analysis tube having an internal zone formed as a passage for the ion beam; and a shield member mounted to an inner wall surface of the analyzing tube, a portion of the shield member intersecting with a direction perpendicular to a traveling direction of an ion beam and a mass-based separation direction of the ion beam so as to block a portion of the ion beam.

Embodiments described herein relate to methods and apparatus for forming gratings having a plurality of fins with different slant angles on a substrate and forming fins with different slant angles on successive substrates using angled etch systems and/or an optical device. The methods include positioning portions of substrates retained on a platen in a path of an ion beam. The substrates have a grating material disposed thereon. The ion beam is configured to contact the grating material at an ion beam angle ϑ relative to a surface normal of the substrates and form gratings in the grating material.

There is provided a deflector that produces only a weak resulting combined hexapole field. The deflector (100) has first to sixth coils (11-16). The first to third coils (11-13) are equal in direction of energization. The fourth to sixth coils (14-16) are equal in direction of energization. The first coil (11) and fourth coil (14) are opposite in direction of energization. The first, third, fourth, and sixth coils (11, 13, 14, 16) are equal in electromotive force. The second coil (12) is equal in electromotive force to the fifth coil (15) and twice the electromotive force of the first coil (11).

To provide a scanning electron microscope having an electron spectroscopy system to attain high spatial resolution and a high secondary electron detection rate under the condition that energy of primary electrons is low, the scanning electron microscope includes: an objective lens 105; primary electron acceleration means 104 that accelerates primary electrons 102; primary electron deceleration means 109 that decelerates the primary electrons and irradiates them to a sample 106; a secondary electron deflector 103 that deflects secondary electrons 110 from the sample to the outside of an optical axis of the primary electrons; a spectroscope 111 that disperses secondary electrons; and a controller that controls application voltage to the objective lens, the primary electron acceleration means and the primary electron deceleration means so as to converge the secondary electrons to an entrance of the spectroscope.

An apparatus is provided for microscopy, inspection, or analysis of a sample. The apparatus has a vacuum chamber and a charged-particle beam column in the vacuum chamber to direct a charged-particle beam onto a sample. The charged-particle beam column includes a charged-particle beam source to generate a charged-particle beam and charged-particle beam optics to direct the charged-particle beam onto the sample. The apparatus has a detector to detect radiation emanating from the sample to generate an image. A cartridge is provided to support the sample in the path of the charged-particle beam in the vacuum chamber. The cartridge is mechanically decoupled from the environment external to the vacuum chamber. A controller is provided to analyze the detected radiation to generate an image of the sample.