A volume interrogation system can use an accelerated beam of charged particles to interrogate objects using charged-particle attenuation and scattering tomography to screen items such as electronic devices, packages, baggage, industrial products, or food products for the presence of materials of interest inside. The apparatus, systems, and methods in this patent document can be employed in checkpoint applications to scan items. Such checkpoint applications can include border crossings, mass transit terminals (subways, buses, railways, ferries, etc.), and government and private-sector facilities.

The present invention relates to a sensor for electron detection emitted from an object to be used with a charged particle beam column being operated at a certain column and wafer voltage. The sensor is configured and operable to at least reduce interaction of negative ions with the active area of the sensor while minimizing electrons energy loss. The sensor is also configured and operable to minimize both gradual degradation of a cathodoluminescence efficiency of the active area and dynamic change of cathodoluminescence generated during operation of the sensor and evolving throughout the scintillator's lifetime.

The present invention provides a charged particle beam apparatus that covers a wide range of detection angles of charged particles emitted from a sample. Accordingly, the present invention proposes a charged particle beam apparatus that is provided with an objective lens for converging charged particle beams emitted from a charged particle source, and a detector for detecting charged particles emitted from a sample, wherein: the objective lens includes an inner magnetic path and an outer magnetic path which are formed so as to enclose a coil; the inner magnetic path comprises a first inner magnetic path disposed at a position opposite to an optical axis of the charged particle beams and a second inner magnetic path which is formed at a slant with respect to the optical axis of the charged particle beams and which includes a leading end of the magnetic path; and a detection surface of the detector is disposed at the outer side from a virtual straight line that passes through the leading end of the magnetic path and that is parallel to the optical axis of the charged particle beams.

Systems and methods to focus and align multiple electron beams are disclosed. A camera produces image data of light from electron beams that is projected at a fiber optics array with multiple targets. An image processing module determines an adjustment to a voltage applied to a relay lens, a field lens, or a multi-pole array based on the image data. The adjustment minimizes at least one of a displacement, a defocus, or an aberration of one of the electron beams. Using a control module, the voltage is applied to the relay lens, the field lens, or the multi-pole array.

Signal electrons with high energy that pass near an optical axis, for example, backscattered electrons or secondary electrons in a booster optical system, can be detected. Therefore, there is provided a charged particle beam device including: a charged particle beam source configured to generate a charged particle beam; an objective lens configured to focus the charged particle beam to a sample; and a first charged particle detecting element disposed between the charged particle beam source and the objective lens and configured to detect charged particles generated by an interaction between the charged particle beam and the sample, in which a detection surface of the first charged particle detecting element is disposed on a center axis of the objective lens.

A method for detector equalization during the imaging of objects with a multi-beam particle microscope includes performing an equalization on the basis of individual images in or on the basis of overlap regions. For detector equalization, contrast values and/or brightness values are used and iterative methods can be employed.

A scintillator assembly including an entrance surface for receiving charged particles into the scintillator assembly, the charged particles including first charged particles at a first energy level and second charged particles at a second energy level. A first scintillator structure configured for receiving the first charged particles and generating a corresponding first signal formed of first photons with a first wavelength of λ1, a second scintillator structure configured for receiving the second charged particles and generating a corresponding second signal of second photons with a second wavelength of λ2, and an emitting surface for egress of a combined signal from the scintillator assembly, the combined signal including the first and second photons, and at least one beam splitter for receiving the combined signal and separating the combined signal to first and second photons.

A charged particle beam apparatus using a light guide that improves light utilization efficiency includes a detector including a scintillator for emitting light when a charged particle is incident, a light receiving element, and a light guide for guiding the light from the scintillator to the light receiving element. The light guide includes: an incident surface that faces a light emitting surface of the scintillator and to which the light emitted by the scintillator is incident; an emitting surface that is configured to emit light; and a reflecting surface that is inclined with respect to the incident surface so that the light from the incident surface is reflected toward the emitting surface. The emitting surface is smaller than the incident surface. A slope surface is provided between the incident surface and the emitting surface, faces the reflecting surface, and is inclined with respect to the incident surface.

An electron beam inspection system is disclosed, in accordance with one or more embodiments of the present disclosure. The inspection system may include an electron beam source configured to generate one or more primary electron beams. The inspection system may also include an electron-optical column including a set of electron-optical elements configured to direct the one or more primary electron beams to a sample. The inspection system may further include a detection assembly comprising: a scintillator substrate configured to collect electrons emanating from the sample, the scintillator substrate configured to generate optical radiation in response to the collected electrons; one or more light guides; one or more reflective surfaces configured to receive the optical radiation and direct the optical radiation along the one or more light guides; and one or more detectors configured to receive the optical radiation from the light guide.

A scintillator assembly including an entrance surface for receiving charged particles into the scintillator assembly, the charged particles including first charged particles at a first energy level and second charged particles at a second energy level. A first scintillator structure configured for receiving the first charged particles and generating a corresponding first signal formed of first photons with a first wavelength of λ1, a second scintillator structure configured for receiving the second charged particles and generating a corresponding second signal of second photons with a second wavelength of λ2, and an emitting surface for egress of a combined signal from the scintillator assembly, the combined signal including the first and second photons, and at least one beam splitter for receiving the combined signal and separating the combined signal to first and second photons.