According to various embodiments, an inspection device may include a chamber, a stage provided within the chamber, an electron emitter, a laser emitter, and a conductive probe. The stage may be configured to hold a sample. The electron emitter may be configured to emit an electron beam towards the stage, to generate a first electrical signal in the sample. The laser emitter may be configured to emit a laser beam towards the stage, to generate a second electrical signal in the sample. The conductive probe may be configured to receive from the conductive structure, at least one of the first electrical signal and the second electrical signal.

The present disclosure provides a substrate processing apparatus including at least one input/output chamber. The load lock device includes a base, a guide rail, a platform and an optical measuring module. The guide rail is connected to the base. The platform, carrying a cassette for holding a batch of spaced substrates, is movably disposed on the guide rail. The optical measuring module is configured to acquire an actual moving distance traveled by the platform along the guide rail based on at least one optical signal reflected from the platform.

An inspection apparatus for adjusting a working height for a substrate for multiple target heights is disclosed. The inspection apparatus includes a radiation source configured to provide a radiation beam and a beam splitter configured to split the radiation beam into multiple beamlets that each reflect off a substrate. Each beamlet contains light of multiple wavelengths. The inspection apparatus includes multiple light reflecting components, wherein each light reflecting component is associated with one of the beamlets reflecting off the substrate and is configured to support a different target height for the substrate by detecting a height or a levelness of the substrate based on the beamlet reflecting off the substrate.

A system for laser enhanced voltage contrast using an optical fiber is provided. The system includes a vacuum chamber with a stage that secures a wafer. A laser light source outside the vacuum chamber directs light to an optical fiber. The optical fiber transmits all wavelengths of light from the laser light source into the vacuum chamber through a wall of the vacuum chamber.

An electron beam inspection apparatus includes a plurality of electrodes to surround an inspection substrate placed on a stage, a camera to measure, for each of the plurality of electrodes, a gap between a peripheral edge of the inspection substrate and an electrode of the plurality of electrodes, a retarding potential application circuit to apply a retarding potential to the inspection substrate, an electrode potential application circuit to apply, to each electrode, a corresponding potential of potentials each obtained by adding an offset potential, which is variable according to a measured gap, to the retarding potential to be applied to the inspection substrate, and an electron optical system to irradiate the inspection substrate with electron beams, in the state where the retarding potential has been applied to the inspection substrate and the corresponding potential of the potentials has been individually applied to each of the plurality of electrodes.

Method for investigating samples by time-series emission of cathodoluminescence (CL) microscope having electron beam and light sensor. In discovery scan, changes caused by the electron beam are unknown, in an inspection scan changes have already been identified in similar sample. Discovery scan starts by setting parameters of the electron beam to irradiate at a first rate of dose; flushing the buffer of the light sensor; scanning the electron beam over an area of interest on the sample while collecting CL emission with the light sensor, while preventing any reading of the data from the buffer until the entire scanning has been completed; once the entire scanning has been completed, blanking the electron beam and interrogating the buffer to identify a first CL image; and then interrogating the buffer to fetch all remaining CL images and tagging all fetched CL images according to time sequence starting from the first CL image.

Apparatuses for collection of upstream and downstream transmission electron microscopy (TEM) cathodoluminescence (CL) emitted from a sample exposed to an electron beam are described. A first fiber optic cable carries first CL light emitted from a first TEM sample surface, into a spectrograph. A second fiber optic cable carries second CL light emitted from a second TEM sample surface into the spectrograph. The first and second fiber optic cables are positioned such that the spectrograph produces a first light spectrum for the first fiber optic cable and a separate light spectrum for the second fiber optic cable. The described embodiments allow collection of TEM CL data in a manner that allows analyzing upstream and downstream TEM CL signals separately and simultaneously with an imaging spectrograph.

The invention relates to a device and method for determining a property of a sample that is to be used in a charged particle microscope. The sample comprises a specimen embedded within a matrix layer. The device comprises a light source arranged for directing a beam of light towards said sample, and a detector arranged for detecting light emitted from said sample in response to said beam of light being incident on said sample. Finally, the device comprises a controller that is connected to said detector and arranged for determining a property of said matrix layer based on signals received by said detector.

A system combination includes a particle beam system and a light-optical system. The particle beam system can be an individual particle beam system or a multiple particle beam system. A light entry mechanism can provided at a branching site of a beam tube arrangement within a beam switch. A light beam of the light-optical system can enter into the beam tube arrangement through the light entry mechanism such that the light beam impinges, in substantially collinear fashion with particle radiation, on an object to be inspected. Parts of the light-optical beam path and parts of the particle-optical beam path can extend parallel to one another or overlap with one another. This arrangement can allow light of the light-optical system to be incident in perpendicular fashion on an object to be inspected, optionally without impairing the particle-optical resolution of the particle beam system.

A method for chemical identification of a sample having nanostructures includes the steps of irradiating the surface at wavelengths for each of a first and a second of the nanostructures that are uniquely absorbed by each of the first nanostructure and the second nanostructure such that each is excited to modulate at a first or a second nanostructure frequency, respectively. The method continues with the steps of irradiating the surface with electron beams incident on each of the first and second nanostructure, wherein at least one of secondary electrons, backscattered electrons and transmitted electrons are modulated at the frequency corresponding to each of the first and second nanostructure frequencies. A chemical map of the sample at an atomic scale is then created. A microscope is provided to carry out the method.