To stabilize automated MS, provided is a charged particle beam apparatus, which is configured to automatically fabricate a sample piece from a sample, the charged particle beam apparatus including: a charged particle beam irradiation optical system configured to radiate a charged particle beam; a sample stage configured to move the sample that is placed on the sample stage; a sample piece transportation unit configured to hold and convey the sample piece separated and extracted from the sample; a holder fixing base configured to hold a sample piece holder to which the sample piece is transported; and a computer configured to perform control of a position with respect to a target, based on: a result of second determination about the position, which is executed depending on a result of first determination about the position; and information including an image that is obtained by irradiation with the charged particle beam.

Processing an object using a material processing device with a particle beam apparatus includes determining a region of interest of the object on or in a first material region of the object, ablating material from a second material region adjoining the first material region using an ablation device, and recognizing a geometric shape of the first material region. The geometric shape has a center. Processing the object also includes ablating material from a second portion of the first material region adjoining a first portion using a particle beam, the first portion having a first subregion and a second subregion, the region of interest being arranged in the first subregion, recognizing a further geometric shape of the first material region, positioning the object such that the first position corresponds to a center of the further geometric shape, and ablating material from the second subregion using the particle beam.

Methods and apparatuses for capturing volume information of microscopic samples include a microscope system having at least one particle beam column, by which a beam of focused, charged particles can be generated, and an in-situ microtome, i.e., a microtome integrated in the microscope system. The method cam include a) providing a sample including a volume of interest (VOI); b) setting a cut surface lying within the sample; c) defining the set cut surface as processing surface; d) exposing the cut surface by virtue of ablating sample material by cutting with the in-situ microtome; and e) processing the sample with the particle beam, wherein the start point of the processing is disposed on the exposed processing surface.

A method for measuring conductance of a material real-time during etching/milling includes providing a fixture having a socket for receiving the material. The socket is attached to a printed circuit board (PCB) mounted on one side of a plate that has at least one opening for providing ion beam access to the material sample. Conductive probes extend from the other side of the PCB to contact and span a target area of the material. A measurement circuit in electrical communication with the probes measures the voltage produced when a current is applied across the material sample to measure changes in electrical properties of the sample over time.

Provided is an inspection apparatus including: an irradiation source irradiating a first pattern formed on an inspection target object with an electron beam; a detection circuit acquiring a first inspection image generated from the first pattern by irradiation; a filter circuit performing smoothing using a local region having a first size in a direction parallel to a first outline included in the first inspection image and a second size smaller than the first size in a direction perpendicular to the first outline and acquiring a second inspection image including a second outline generated by the smoothing; and a comparison circuit comparing the second inspection image with a predetermined reference image.

Linear fiducials including notches or chevrons with known angles relative to each other are formed such that each branch of a chevron appears in a cross-sectional face of the sample as a distinct structure. Therefore, when imaging the cross-section face during the cross-sectioning operation, the distance between the identified structures allows unique identification of the position of the cross-section plane along the Z axis. Then a direct measurement of the actual position of each slice can be calculated, allowing for dynamic repositioning to account for drift in the plane of the sample and also dynamic adjustment of the forward advancement rate of the FIB to account for variations in the sample, microscope, microscope environment, etc. that contributes to drift. An additional result of this approach is the ability to dynamically calculate the actual thickness of each acquired slice as it is acquired.

An inspection device includes a charged particle optical system that includes a charged particle beam source emitting a charged particle beam and plural lenses focusing the charged particle beam on a sample, a detector that detects secondary charged particles emitted by an interaction of the charged particle beam and the sample, and a calculation unit that executes auto-focusing at a time a field of view of the charged particle optical system moves over plural inspection spots, the calculation unit irradiates the charged particle beam to the sample under an optical condition that is obtained by introducing astigmatism of a predetermined specification to an optical condition that is for observing a pattern by the charged particle optical system, and executes the auto-focusing using an image formed from a signal outputted by the detector in detecting the secondary charged particles.

Producing and storing a first image, of a first, initial surface of the specimen; In a primary modification step, modifying said first surface, thereby yielding a second, modified surface; Producing and storing a second image, of said second surface; Using a mathematical Image Similarity Metric to perform pixel-wise comparison of said second and first images, so as to generate a primary figure of merit for said primary modification step.

A writing data generating method for generating writing data used in a multi charged particle beam writing apparatus, that can suppress a data amount and a calculation amount in a multi charged particle beam writing apparatus generated from design data including a figure having a curve. The method includes calculating a pair of curves each representing a curve portion of a figure included in design data, the curves each being defined by a plurality of control points, and generating the writing data by expressing a position of a second control point adjacent in a traveling direction of the curve to a first control point of the plurality of control points as a displacement from the first control point in the traveling direction of the curve and a displacement from the first control point in a direction orthogonal to the traveling direction.

Provided herein are systems and methods for spatially resolved optical metrology of an ion beam. In some embodiments, a system includes a chamber containing a plasma/ion source operable to deliver an ion beam to a wafer, and an optical collection module operable with the chamber, wherein the optical collection module includes an optical device for measuring a light signal from a volume of the ion beam. The system may further include a detection module operable with the optical collection module, the detection module comprising a detector for receiving the measured light signal and outputting an electric signal corresponding to the measured light signal, thus corresponding to the property of the sampled plasma volume.