A plurality of energy filter values are obtained using a model that simulates potential distribution within a 3D feature when an electron beam of an SEM impinges on a selected area that includes the 3D feature. A correspondence is extracted between the plurality of energy filter values and respective depths of the 3D feature along a longitudinal direction by analyzing the simulated potential distribution. A plurality of SEM images of the 3D feature corresponding to the plurality of energy filter values are obtained. The plurality of SEM images are associated with their respective depths based on the extracted correspondence between the plurality of energy filter values and the respective depths. A composite 3D profile of the 3D feature is generated from the plurality of SEM images obtained from various depths of the 3D feature.

A scanning electron microscopy system with improved image beam stability is disclosed. The system includes an electron beam source configured to generate an electron beam and a set of electron-optical elements to direct at least a portion of the electron beam onto a portion of the sample. The system includes an emittance analyzer assembly. The system includes a splitter element configured to direct at least a portion secondary electrons and/or backscattered electrons emitted by a surface of the sample to the emittance analyzer assembly. The emittance analyzer assembly is configured to image at least one of the secondary electrons and/or the backscattered electrons.

A method for implanting high charge state ions into a workpiece while mitigating trace metal contamination includes generating desired ions at a first charge state from a desired species in an ion source, as well as generating trace metal ions of a contaminant species in a first ion beam. A charge-to-mass ratio of the desired ions and the trace metal ions is equal. The desired ions and trace metal ions are extracted from the ion source. At least one electron stripped from the desired ions to define a second ion beam of the desired ions at a second charge state and the trace metal ions. Only the desired ions from the second ion beam are selectively passed only through a charge selector to define a final ion beam of the desired ions at the second charge state and no trace metal ions, and the desired ions of the second charge state are implanted into a workpiece.

An improved ANAB system or process substantially or fully eliminating contaminant particles from reaching a beam target by adding to the usual primary (first) ionizer of the ANAB system or process an additional (second) ionizer to ionize contaminant particles and means to block or retard the ionized particles to prevent their reaching the beam target.

In order to optimize defect contrast in a charged particle beam device that inverts charged particles directly above a sample and observes the electrons, this charged particle beam device is provided with a charged particle source, an electron gun control device which applies a first voltage to the charged particle source, a substrate voltage control device which applies a second voltage to a sample, an image forming optical system which includes an imaging lens for imaging charged particles incident from the direction of the sample, a detector which includes a camera for detecting the charged particles, and an image processing device which processes the detected signal, wherein the imaging optical system is configured so as not to image secondary electrons emitted from the sample, but forms an image with mirror electrons bounced back by the electric field formed on the sample by means of the potential difference between the first and the second voltages. The image processing device generates a control signal for controlling the potential difference on the basis of the acquired signal, and optimizes defect contrast by controlling the reflection surface of the mirror electrons.

Systems and methods for implementing charged particle flooding in a charged particle beam apparatus are disclosed. According to certain embodiments, a charged particle beam system includes a charged particle source and a controller which controls the charged particle beam system to emit a charged particle beam in a first mode where the beam is defocused and a second mode where the beam is focused on a surface of a sample.

Systems and methods of providing a probe spot in multiple modes of operation of a charged-particle beam apparatus are disclosed. The method may comprise activating a charged-particle source to generate a primary charged-particle beam and selecting between a first mode and a second mode of operation of the charged-particle beam apparatus. In the flooding mode, the condenser lens may focus at least a first portion of the primary charged-particle beam passing through an aperture of the aperture plate to form a second portion of the primary charged-particle beam, and substantially all of the second portion is used to flood a surface of a sample. In the inspection mode, the condenser lens may focus a first portion of the primary charged-particle beam such that the aperture of the aperture plate blocks off peripheral charged-particles to form the second portion of the primary charged-particle beam used to inspect the sample surface.

A purpose of the present invention is to provide a charged particle beam apparatus that performs apparatus adjustment based on a proper evaluation of a beam. To achieve the abovementioned purpose, with the present invention, proposed is a charged particle beam apparatus comprising: an irradiation optical system including a lens for converging charged particle beams emitted from a charged particle source; and an imaging optical system for imaging the charged particles obtained by irradiating the charged particle beams toward a sample on an imaging element, wherein the charged particle beam apparatus comprises a control apparatus for controlling the lens, and the control apparatus evaluates for each lens condition the size of a specific brightness area obtained by the charged particle beam being made to reach the sample, and selects the lens condition for which the size information fulfills a designated condition.

An inspection method of an embodiment includes: positively charging a substrate on which a pattern is formed by irradiating the substrate with a first electron beam; generating a secondary electron on a surface of the substrate by irradiating the substrate with a second electron beam; detecting the generated secondary electron; and inspecting the pattern based on the detected secondary electron, in which when the substrate is irradiated with the first electron beam, the first electron beam is made incident on the substrate at an incident angle different from an incident angle of the second electron beam with respect to the substrate, while positions of an emission source of the first electron beam and the substrate are being moved relatively.

Charged particle beam systems and methods, such as a multi beam charged particle beam system and related methods, can compensate sample charging.