Method and system are disclosed for determining sample composition from spectral data acquired by a charged particle microscopy system. Chemical elements in a sample are identified by processing the spectral data with a trained neural network (NN). If the identified chemical elements not matching with a known elemental composition of the sample, the trained NN is retrained with the spectral data and the known elemental composition of the sample. The retrained NN can then be used to identify chemical elements within other samples.

Method and system are disclosed for determining sample composition from spectral data acquired by a charged particle microscopy system. Chemical elements in a sample are identified by processing the spectral data with a trained neural network (NN). If the identified chemical elements not matching with a known elemental composition of the sample, the trained NN is retrained with the spectral data and the known elemental composition of the sample. The retrained NN can then be used to identify chemical elements within other samples.

The present invention is intended to provide improved patterned X-ray emitting targets as well as X-ray sources that include patterned X-ray emitting targets as well as X-ray reflectance scatterometry (XRS) systems and also including X-ray photoelectron spectroscopy (XPS) systems and X-ray fluorescence (XRF) systems which employ such X-ray emitting targets.

Methods and systems for imaging a sample with a charged particle microscope comprises after scanning a region of interest (ROI) of a sample with an electron beam and acquiring X-rays emitted from the sample, scanning the ROI with an ion beam and acquiring ion-induced photons emitted from the sample. A spatial distribution of multiple elements in the sample may be determined based on both the acquired X-rays and the acquired ion-induced photons.

An analyzer includes a wavelength-dispersive X-ray spectrometer and a control unit that controls the wavelength-dispersive X-ray spectrometer, the control unit performing: processing of acquiring an analysis result of preparatory analysis performed on a specimen to be analyzed; processing of setting spectroscopic conditions for WDS analysis using the wavelength-dispersive X-ray spectrometer based on the analysis result of the preparatory analysis; and processing of performing the WDS analysis on the specimen to be analyzed under the set spectroscopic conditions.

A magnetic material observation method in accordance with the present invention includes: an irradiating step including irradiating a region of a sample with an excitation beam and thereby allowing a magnetic element contained in the sample to radiate a characteristic X-ray; a detecting step including detecting intensities of a right-handed circularly polarized component and a left-handed circularly polarized component contained in the characteristic X-ray; and a calculating step including calculating the difference between the intensity of the right-handed circularly polarized component and the intensity of the left-handed circularly polarized component. Reference to such a difference enables precise measurement of the direction or magnitude of magnetization without strict limitations as to the sample.

A method for improving a quality of a secondary electron image of a region of a sample, the method may include obtaining a backscattered electron (BSE) image of the region and a secondary electron (SE) image of the region; wherein the BSE image and the SE image are generated by scanning of the region with an electron beam; processing the BSE image and the SE image to provide a processed BSE image and a processed SE image; and generating a BSE compensated SE image, wherein the generating comprises applying one or more selected BSE correction factors on one or more parts of the processed BSE image.

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.

A method for analyzing the quality of a thin layer surface of PCB includes steps of taking a region to be tested from the PCB as a sample by scissors or an automatic sampler; performing gold spraying treatment; fixing a sample to be tested onto a metal sample platform, and then mounting the sample platform on the inclined surface of a test platform; depositing a first protective layer by an electron beam; after deposition with the electron beam is completed, depositing a second protective layer by a focused ion beam; adjusting the angle of inclination of the test platform to ensure that the surface of the sample can be cut perpendicular to the direction of the focused ion beam; and finally adjusting angle of inclination of the sample to perform observation. The method can avoid influences of chemical solutions, mechanical stress, and impurity contamination in the sample preparation process.

The invention relates to a method for ablating a material (1) from a material unit (502) and for arranging the material (1) on an object (125), the object (125) being arranged in a particle beam apparatus. Further, the invention relates to a computer program product, and to a particle beam apparatus for carrying out the method. The method comprises feeding a particle beam with charged particles onto the material (1), wherein the material (1) is arranged on the material unit (502) and/or wherein the material unit (502) is formed from the material (1), wherein the material (1) is ablatable from the material unit (502) and wherein the material (1) is arranged on the material unit (502) at a distance from the object (125).

Further, the method comprises ablating the ablatable material (1) arranged on the material unit (502) from the material unit (502) using the particle beam, and arranging the ablated material (514) on the object (125).