A method for analyzing a sample with a charged particle beam including directing the beam toward the sample surface; milling the surface to expose a second surface in the sample in which the end of the second surface distal to ion source is milled to a greater depth relative to a reference depth than the end of the first surface proximal to ion source; directing the charged particle beam toward the second surface to form one or more images of the second surface; forming images of the cross sections of the multiple adjacent features of interest by detecting the interaction of the electron beam with the second surface; assembling the images of the cross section into a three-dimensional model of one or more of the features of interest. A method for forming an improved fiducial and determining the depth of an exposed feature in a nanoscale three-dimensional structure is presented.

A method, a non-transitory computer readable medium and a three-dimensional evaluation system for providing three dimensional information regarding structural elements of a specimen. The method can include illuminating the structural elements with electron beams of different incidence angles, where the electron beams pass through the structural elements and the structural elements are of nanometric dimensions; detecting forward scattered electrons that are scattered from the structural elements to provide detected forward scattered electrons; and generating the three dimensional information regarding structural elements based at least on the detected forward scattered electrons.

In one embodiment, a method for detecting edge positions in a pattern structure is disclosed. The method includes detecting the edge positions of features within the pattern structure of an image without filtering the image, wherein the detecting is performed by: applying a model to a single linescan, adjusting, based on the single linescan, one or more parameters of the model, obtaining, using the one or more adjusted parameters, a best fit of the model to the single linescan.

A simulated tool signal is determined from design data and tool properties of the tool making the measurements. A design-assisted composite signal is determined from measurements. An edge placement uniformity signal is then determined by comparing the simulated tool signal and the design-assisted composite signal. A shape and/or an area of the edge placement uniformity signal can be analyzed. The edge placement uniformity signal enables screening of structures with respect to wafer stochastics without the need to fully characterize all individual structures.

Pulsed beam prober systems, devices, and techniques are described herein related to providing a beam detection frequency that is less than a electrical test frequency. An electrical test signal at the electrical test frequency is provided to die under test. A pulsed beam is applied to the die such that the pulsed beam has packets of beam pulses or a frequency delta with respect to the electrical test frequency. The packets of beam pulses or the frequency delta elicits a detectable beam modulation in an imaging signal reflected from the die such that the imaging signal is modulated at a detection frequency less than the electrical test frequency.

In one embodiment, a method includes determining, by a processor, a measurement of edge detection noise; receiving a measurement of a biased parameter including measurement noise; based on the measurement of edge detection noise and a number of measurement points, determining a contribution of edge detection noise to the biased parameter; determining an unbiased parameter by subtracting the contribution of noise from the biased parameter including the measurement noise; and outputting the unbiased parameter.

An improved particle beam inspection apparatus, and more particularly, a particle beam inspection apparatus including a thermal conditioning station for preconditioning a temperature of a wafer is disclosed. The charged particle beam apparatus may scan the wafer to measure one or more characteristics of the structures on the wafer and analyze the one or more characteristics. The charged particle beam apparatus may further determine a temperature characteristic of the wafer based on the analysis of the one or more characteristics of the structure and adjust the thermal conditioning station based on the temperature characteristic.

A purpose of the present invention is to provide a pattern measurement device that allows the selection of device conditions for calculating proper variability and allows the estimation of proper variability. The present invention provides a pattern measurement device comprising a computation processing device that, on the basis of a plurality of measured values acquired by a charged particle radiation device, calculates the variability of the measured values of a pattern that is the object of measurement, said pattern measurement device characterized in that a variability σ.sub.measured of the plurality of measured values formed at different positions and σ.sup.2.sub.observed=σ.sup.2.sub.pattern/Np+σ.sup.2.sub.sem0/(Np.Math.Nframe) are used to calculate σ.sub.SEM0, which indicates measurement reproducibility error. σ.sub.pattern0 is the variability due to pattern shape error, Np is the number of measurement points, and Nframe is a value that changes according to device conditions.

To implement a calibration sample by which an incident angle can be measured with high accuracy, an electron beam adjustment method, and an electron beam apparatus using the calibration sample. To adjust an electron beam using a calibration sample, the calibration sample includes a silicon single crystal substrate 201 whose upper surface is a {110} plane, a first recess structure 202 opening in the upper surface and extending in a first direction, and a second recess structure 203 opening in the upper surface and extending in a second direction intersecting the first direction, in which the first recess structure and the second recess structure each include a first side surface and a first bottom surface that intersects the first side surface, and a second side surface and a second bottom surface that intersects the second side surface, the first side surface and the second side surface are {111} planes, and the first bottom surface and the second bottom surface are crystal planes different from the {110} planes.

Methods, systems, and devices for electron beam probing techniques and related structures are described to enable inline testing of memory device structures. Conductive loops may be formed, some of which may be grounded and others of which may be electrically floating in accordance with a predetermined pattern. The loops may be scanned with an electron beam and image analysis techniques may be used to generate an optical pattern. The generated optical pattern may be compared to an expected optical pattern, which may be based on the predetermined pattern of grounded and floating loops. An electrical defect may be determined based on any difference between the generated optical pattern and the expected optical pattern. For example, if a second loop appears as having a brightness corresponding to a grounded loop, this may indicate that an unintended short exists. Fabrication techniques may be adjusted for subsequent devices to correct identified defects.