An electron beam is directed at a workpiece on a stage with a first astigmatism applied. The electron beam reflected off the workpiece is detected and an image of the workpiece with the first astigmatism applied is generated. An autofocus model is applied to the image to determine a focus offset for the image with the autofocus model.

A novel sample holder for specimen support devices for insertion in electron microscopes. The novel sample holder of the invention allows for the introduction of gases or liquids to specimens for in situ imaging, as well as electrical contacts for electrochemical or thermal experiments.

A novel sample holder for specimen support devices for insertion in electron microscopes. The novel sample holder of the invention allows for the introduction of gases or liquids to specimens for in situ imaging, as well as electrical contacts for electrochemical or thermal experiments.

A novel sample holder for specimen support devices for insertion in electron microscopes. The novel sample holder of the invention allows for the introduction of gases or liquids to specimens for in situ imaging, as well as electrical contacts for electrochemical or thermal experiments.

The present disclosure provides a system for imaging a signal charged particle beam emanating from a sample by impingement of a primary charged particle beam. The system includes a detector arrangement having a first detection element for detecting a first signal charged particle sub-beam of the signal charged particle beam originating from a first spot on the sample and a second detection element for detecting a second signal charged particle sub-beam of the signal charged particle beam originating from a second spot on the sample, wherein the first detection element and the second detection element are separated from each other, and signal charged particle optics. The signal charged particle optics includes a coil configured to generate a magnetic field having a magnetic field component parallel to a longitudinal axis of the coil, wherein the magnetic field acts on the first signal charged particle sub-beam and the second signal charged particle sub-beam propagating along the longitudinal axis, and wherein an aspect ratio of the coil is at least 1, and a controller configured to adjust the magnetic field of the coil such that the first signal charged particle sub-beam is directed towards the first detection element and the second signal charged particle sub-beam is directed towards the second detection element.

The present application discloses methods, systems and devices for using charged particle beam tools to inspect and perform lithography on a substrate using a combination of vectoring to move a beam to features to be imaged, and raster scanning to obtain an image of the feature(s). The inventors have discovered that it is highly advantageous to use an extra step, a fast raster scan to image the substrate at a lower resolution, to determine which features receive priority for inspection; this extra step can reduce total inspection time, enhance inspection results, and improve beam alignment and manufacturing yield. Using multiple beam-producing columns, with multiple control computers local to the columns, provides various synergies. Preferably, miniature, non-magnetic, electrostatically-driven columns are used.

Multi-beam scanning electron microscope (SEM) inspection systems with dark field imaging capabilities are disclosed. An SEM inspection system may include an electron source and at least one optical device. The at least one optical device may be configured to produce a plurality of primary beamlets utilizing electrons provided by the electron source and deliver the plurality of primary beamlets toward a target. The apparatus may also include an array of detectors configured to receive a plurality of image beamlets emitted by the target in response to the plurality of primary beamlets and produce at least one dark field image of the target.

An electron source is formed on a silicon substrate having opposing first and second surfaces. At least one field emitter is prepared on the second surface of the silicon substrate to enhance the emission of electrons. To prevent oxidation of the silicon, a thin, contiguous boron layer is disposed directly on the output surface of the field emitter using a process that minimizes oxidation and defects. The field emitter can take various shapes such as pyramids and rounded whiskers. One or several optional gate layers may be placed at or slightly lower than the height of the field emitter tip in order to achieve fast and accurate control of the emission current and high emission currents. The field emitter can be p-type doped and configured to operate in a reverse bias mode or the field emitter can be n-type doped.

A novel sample holder for specimen support devices for insertion in electron microscopes. The novel sample holder of the invention allows for the introduction of gases or liquids to specimens for in situ imaging, as well as electrical contacts for electrochemical or thermal experiments.

A scanning electron microscope according to the present invention includes: an electron source that produces an electron beam; a trajectory dispersion unit that disperses the trajectory of an electron beam of electrons with a different energy value; a selection slit plate having a selection slit that selects the energy range of the dispersed electron beam; and a transmittance monitoring unit that monitors the transmittance of an electron beam, which is being transmitted through the selection slit. Accordingly, there can be provided a scanning electron microscope equipped with an energy filter that implements a stable reduction in energy distribution.