A method of operating a charged particle beam device is disclosed, including focusing a charged particle beam onto a sample with an objective lens assembly; passing a reflected light beam through a bore of the objective lens assembly to an interferometer; and interferometrically determining a z-position of the sample with the interferometer. A charged particle beam device is disclosed, including a charged particle beam generator which has a charged particle source. A charged particle path for the charged particle beam extends through a bore of an objective lens assembly toward a sample stage. An interferometer is arranged to receive a reflected light beam which passes through the bore of the objective lens assembly.

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.

The present invention is in the field of a cryo transfer system for use in microscopy, and a microscope comprising said system. The present invention is in the field of microscopy, specifically in the field of electron and focused ion beam microscopy (EM and FIB), and in particular Transmission Electron Microscopy (TEM). However its application is extendable in principle to any field of microscopy, especially wherein a specimen (or sample) is cooled or needs cooling.

A charged particle beam writing apparatus includes a writer writing a pattern on a surface of a substrate using a charged particle beam, a measurement unit measuring a height of the surface of a central portion of the substrate at a plurality of positions in the central portion, a generator performing fitting using a first polynomial on measurement values from the measurement unit, calculating, by extrapolation using the first polynomial, a first height distribution of the height of the surface of a peripheral portion of the substrate, performing fitting using a second polynomial, which is of a higher order than the first polynomial, on the measurement values, calculating a second height distribution of the height of the surface of the central portion by interpolation using the second polynomial, and generating a height distribution of the substrate by combining the first height distribution and the second height distribution, and a controller adjusting a focal position of the charged particle beam based on the height of the surface at a writing position, the height being calculated from the height distribution of the substrate.

There are provided: a method for image adjustment using a charged particle beam device, and a charged particle beam system, capable of appropriately adjusting a contrast and brightness as well as a focus for a measurement region present in a deep portion of a sample even when a depth of the measurement region is unknown.

A method for image adjustment performed by a computer system controlling a charged particle beam device includes: by the computer system, specifying a measurement region from a captured image of a sample; performing centering processing based on the specified measurement region; extracting the measurement region in a field of view that has undergone the centering processing or the image that has undergone the centering processing; adjusting a contrast and brightness for the extracted measurement region; and adjusting a focus for the measurement region in which the contrast and brightness have been adjusted.

The present disclosure provides a technique for reducing man-hour of a user required for setting an automatic focused focal point search function of an electron beam and facilitating observation of a sample when reviewing a defect using an electron microscope. The present disclosure provides a technique in a charged particle beam system, in which an appropriate focal point position search width can be automatically set in consideration of convergence accuracy and an operation time based on a focal point measure distribution width for a focal point position acquired in advance under the same conditions and a difference between focal point positions before and after automatic focused focal point position search.

The present invention relates to a method for examining a beam of charged particles, including the following steps: producing persistent interactions of the beam with a sample at a plurality of positions of the sample relative to the beam and deriving at least one property of the beam by analyzing the spatial distribution of the persistent interactions at the plurality of positions.

The focused ion beam apparatus includes: an ion source configured to generate ions; a first electrostatic lens configured to accelerate and focus the ions to form an ion beam; a beam booster electrode configured to accelerate the ion beam to a higher level; one or a plurality of electrodes, which are placed in the beam booster electrode, and are configured to electrostatically deflect the ion beam; a second electrostatic lens, which is provided between the one or plurality of electrodes and a sample table, and is configured to focus the ion beam applied with a voltage; and a processing unit configured to obtain a measurement condition, and set at least one of voltages to be applied to the one or plurality of electrodes or a voltage to be applied to each of the first electrostatic lens and the second electrostatic lens, based on the obtained measurement condition.

The present disclosure makes it possible to shorten the time required for measurement of a sample and to measure the sample with high throughput. A charged particle beam apparatus includes a storage device that stores a correction value table corresponding to a recipe and a computer system that executes measurement on a plurality of measurement points of a sample according to a measurement order determined in the recipe. The computer system stores, when executing the recipe on a first sample, an adjustment result of one or more imaging conditions in the correction value table at each of a plurality of measurement points of the first sample, and adjusts, when executing the recipe on a second sample different from the first sample, the imaging condition based on the adjustment result of the one or more imaging conditions stored in the correction value table at each of the plurality of measurement points.

An object of the invention is to provide a charged particle beam apparatus which improves an efficiency of a beam scan at the time of performing a focus adjustment and a measurement or an inspection based on a signal obtained by the beam scan. In order to achieve the object described above, there is proposed a charged particle beam apparatus including a lens which focuses a charged particle beam on a sample, wherein focus evaluation values of a plurality of images are calculated which are obtained under different focus conditions by the lens, the images which are obtained by beam radiation with different focus conditions and in which a predetermined condition is satisfied are subject to a processing according to the focus evaluation values, and an integrated image is generated by integrating the processed images subject to the processing according to the focus evaluation values.