In one embodiment, a writing data generation method is for generating writing data used by a multi-charged particle beam writing apparatus. The writing data generation method includes referring to library data in which a vertex sequence including a plurality of vertices is registered, and extracting a portion of an outer line of a figure contained in design data, the portion corresponding to the vertex sequence, and representing the extracted portion by information which identifies the vertex sequence and information which indicates a connection method for the plurality of vertices of the vertex sequence, and generating the writing data.

A device for creating and placing a lamella comprises a focused ion beam, a scanning electron microscope, a stage for placing at least two specimens enabling tilting, rotation and movement of the specimen. The device further comprises a manipulator terminated by a needle for attaching and transporting the specimen. The manipulator is positioned in a plane perpendicular to the axis of the tilt of the specimen, thereby enabling easy transportation and placing of the lamella into the specimen holder for a transmission electron microscope, so-called grid. The manipulator is adjusted to rotate the needle about its own axis. Thus, it enables inverting of the lamella and its polishing over a layer of semiconductor substrate, on which a semiconductor structure is formed, in case of creating the lamella from a semiconductor device.

The purpose of the present invention is to provide a charged particle beam device with which it is possible to identify, to a high degree of accuracy, repeat patterns generated by a multiple exposure method such as SADP or SAQP. In order to achieve this purpose, there is proposed a charged particle beam device for: irradiating a first position on a sample with a charged particle beam to form an irradiation mark on the sample; after the formation of the irradiation mark, scanning the charged particle beam on a first visual field which includes the first position and which is larger than the irradiation mark, and thereby acquiring a first image; scanning the charged particle beam on a second visual field which includes the first position, which is larger than the irradiation mark, and which is in a different position from the first visual field, thereby acquiring a second image; and synthesizing the first image and the second image so as to overlap the irradiation marks included in the first image and the second image.

A focused ion beam apparatus (100) includes: a focused ion beam lens column (20); a sample table (51); a sample stage (50); a memory (6M) configured to store in advance three-dimensional data on the sample table and an irradiation axis of the focused ion beam, the three-dimensional data being associated with stage coordinates of the sample stage; a display (7); and a display controller (6A) configured to cause the display to display a virtual positional relationship between the sample table (51v) and the irradiation axis (20Av) of the focused ion beam, which is exhibited when the sample stage is operated to move the sample table to a predetermined position, based on the three-dimensional data on the sample table and the irradiation axis of the focused ion beam.

Techniques for planarizing surfaces are disclosed herein. One example includes orienting a surface of a sample to a charged particle beam axis, the sample including a first layer formed from first and second materials, the first material patterned into a plurality of parallel lines and disposed in the second material, where the surface is oriented to form a shallow angle with the charged particle beam axis and to arrange the plurality of parallel lines perpendicular to the charged particle beam axis, providing a charged particle beam toward the surface, providing a gas to the surface, and selectively etching, with ion induced chemical etching, the second material at least down to a top surface of the first material, the charged particle induced etching stimulated due to concurrent presence of the charged particle beam and the gas over the surface of the sample.

An ion implanter includes a beam generator that generates anion beam, a beam scanner that performs reciprocating scan with the ion beam in a first direction, a platen driving device that performs reciprocating motion of a wafer in a second direction perpendicular to the first direction, while holding the wafer so that a wafer processing surface is irradiated with the ion beam subject to the reciprocating scan, and a control device that changes a beam scan speed in the first direction and a wafer motion speed in the second direction in accordance with a beam irradiation position in the first direction and the second direction at which the wafer processing surface is irradiated with the ion beam so that ions having a desired two-dimensional non-uniform dose distribution are implanted into the wafer processing surface.

A plasma etching apparatus for processing a workpiece of a frame unit including the workpiece formed with division start points or division grooves along a plurality of mutually intersecting streets, and a frame that has an opening and that supports the workpiece on inside of the opening through an expanding tape includes a plasma etching unit that has a chuck table for holding the workpiece on a holding surface through the expanding tape and that supplies a plasmatized gas to the workpiece held by the chuck table, and an expanding unit that expands the expanding tape to divide the workpiece along the division start points or to widen a width of the division grooves.

A method includes controlling a multi-scanning electron microscope, mSEM, to capture a first image of a wafer attached to a motorized handling stage while the motorized handling stage is in a first position. The first image includes at least a part of a notch of the wafer. The method also includes determining a radial axis of the wafer based on the first image, and controlling the motorized handling stage to shift the wafer along the radial axis by half a diameter of the wafer so that the motorized handling stage is in a second position. The method further includes controlling the mSEM to capture a second image of the wafer while the motorized handling stage is in the second position. The second image includes wafer structures. In addition, the method includes determining a reference position of the wafer based on a structure recognition of the wafer structures of the second image, and registering a wafer coordinate system of the wafer to a stage coordinate system of the motorized handling stage based on the reference position and the radial axis.

In one embodiment, a multi-beam writing method includes forming a beam array of a multi-beam, assigning sub-beam arrays to each of a plurality of sub-stripe regions, the sub-stripe regions being obtained by dividing a region on the substrate, and the sub-beam arrays being obtained by dividing the beam array, calculating an irradiation time modulation rate being used for each beam belonging to each of the sub-beam arrays, calculating a weight for each of the sub-beam arrays based on the irradiation time modulation rate for each of the beams belonging to a group of the sub-beam arrays, and assigning the calculated weight to the sub-beam array, and performing multiple writing on each of the sub-stripe regions by performing writing on each of the sub-stripe regions with the sub-beam arrays, based on the weight assigned to the sub-beam array and the irradiation time modulation rate of the beam belonging to the sub-beam array.

An apparatus and method for processing a workpiece with a beam is described. The apparatus includes a vacuum chamber having a beam-line for forming a particle beam and treating a workpiece with the particle beam, and a scanner for translating the workpiece through the particle beam. The apparatus further includes a scanner control circuit coupled to the scanner, and configured to control a scan property of the scanner, and a beam control circuit coupled to at least one beam-line component, and configured to control the beam flux of the particle beam according to a duty cycle for switching between at least two different states during processing.