Disclosed herein are CPM support systems, as well as related apparatuses, methods, computing devices, and computer-readable media. For example, in some embodiments, a charged particle microscope computational support apparatus may include: first logic to, for each angle of a plurality of angles, receive an associated image of a specimen at the angle, and generate an associated scan mask based on one or more regions-of-interest in the associated image; second logic to, for each angle of the plurality of angles, generate an associated data set of the specimen by processing data from a scan, in accordance with the associated scan mask, by a charged particle microscope of the specimen at the angle; and third logic to provide, for each angle of the plurality of angles, the associated data set of the specimen to reconstruction logic to generate a three-dimensional reconstruction of the specimen.

The invention relates to a method of examining a sample using a charged particle microscope, comprising the steps of providing a charged particle beam, as well as a sample; scanning said charged particle beam over said sample; and detecting, using a first detector, emissions of a first type from the sample in response to the beam scanned over the sample. Spectral information of detected emissions of the first type is used for assigning a plurality of mutually different phases to said sample. In a further step, a corresponding plurality of different color hues—with reference to an HSV color space—are associated to said plurality of mutually different phases. Using a second detector, emissions of a second type from the sample in response to the beam scanned over the sample are detected. Finally an image representation of said sample is provided.

A method generates a crystalline orientation map of a surface portion of a sample. A crystalline orientation map represents crystalline orientations at a plurality of sample locations of the surface portion. The method comprises recording an image of the surface portion including a central location using particles of a charged particle beam directed to the surface portion and backscattering from the surface portion for each of a plurality of different orientation settings. Each of the orientation settings is defined by an azimuthal angle and an elevation angle under which the charged particle beam is incident onto the central location during the recording of the respective image. The method also includes generating the crystalline orientation map based on the recorded images.

Disclosed herein are CPM support systems, as well as related apparatuses, methods, computing devices, and computer-readable media. For example, in some embodiments, a charged particle microscope computational support apparatus may include: first logic to, for each angle of a plurality of angles, receive an associated image of a specimen at the angle, and generate an associated scan mask based on one or more regions-of-interest in the associated image; second logic to, for each angle of the plurality of angles, generate an associated data set of the specimen by processing data from a scan, in accordance with the associated scan mask, by a charged particle microscope of the specimen at the angle; and third logic to provide, for each angle of the plurality of angles, the associated data set of the specimen to reconstruction logic to generate a three-dimensional reconstruction of the specimen.

The invention relates to a method of examining a sample using a charged particle microscope, comprising the steps of providing a charged particle beam, as well as a sample, and scanning said charged particle beam over at least part of said sample. A first detector is used for obtaining measured detector signals corresponding to emissions of a first type from the sample at a plurality of sample positions. According to the method, a set of data class elements is provided, wherein each data class element relates an expected detector signal to a corresponding sample information value. The measured detector signals are processed, and processing comprises comparing said measured detector signals to said set of data class elements; determining at least one probability that said measured detector signals belong to a certain one of said set of data class elements; and assigning at least one sample information value and said at least one probability to each of the plurality of sample positions. Finally, sample information values and corresponding probability can be represented in data.

The invention relates to a method of examining a sample using a charged particle microscope, comprising the steps of providing a charged particle beam, as well as a sample; scanning said charged particle beam over said sample at a plurality of sample positions; and acquiring an EELS spectrum for each of said plurality of sample positions. According to the method, it comprises the further steps of scanning, once more, said charged particle beam over said sample at said plurality of sample positions; acquiring a further EELS spectrum for each of said plurality of sample positions; and combining, for each of said plurality of sample positions, said EELS spectrum with said further EELS spectrum. With this, it is possible to acquire rapid information on the sample being investigated, allowing for faster processing of samples.

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 disclosure relates to a method of examining a sample using a charged particle microscope. The method comprises the steps of detecting using a first detector emissions of a first type from the sample in response to the beam scanned over the area of the sample. Then, using spectral information of detected emissions of the first type, at least a part of the scanned area of the sample is divided into multiple segments. According to the disclosure, emissions of the first type at different positions along the scan in at least one of said multiple segments may be combined to produce a combined spectrum of the sample in said one of said multiple segments. In an embodiment, a second detector is used to detect emissions of a second type, and this is used to divide the area of the sample into multiple regions. The first detector may be an EDS, and the second detector may be based on EM. This way, EDS data and EM data can be effectively combined for producing colored images.

A data analysis system is disclosed for generating analysis data depending on microscopic data of an object generated by a charged particle microscope. The microscopic data includes an image showing a structure. A graphical representation of the structure is displayed on the display by the graphical user interface. Separation data is generated representing at least one path of a separation cut, which separates pixels of the structure from each other. The separation cut is visually marked by the graphical user interface, depending on the separation data, by differently marking different area portions of the representation, which represent different pixels of the structure which are separated from each other by the separation cut. Separate analysis data are generated for each of at least two portions of the object, depending on the microscopic data and depending on the separation data.

An electron microscope includes: an electron detector which detects electrons emitted from a specimen upon irradiation of the specimen with an electron beam; an X-ray detector which detects X-rays emitted from the specimen upon irradiation of the specimen with the electron beam; and a processor which generates a three-dimensional element map based on output signals from the electron detector and the X-ray detector. The processor performs processing for generating a electron microscopic image based on the output signal from the electron detector, processing for generating a three-dimensional image of the specimen based on the electron microscopic image, processing for generating a two-dimensional element map based on the output signal from the X-ray detector, and processing for generating the three-dimensional element map by projecting the two-dimensional element map on the three-dimensional image.