According to example embodiments, there is provided a photoresist inspection method. The photoresist inspection method includes: providing a photoresist on a substrate; irradiating the photoresist with an electron beam and an excitation beam; detecting fluorescent light generated by the photoresist in response to the excitation beam; and evaluating the photoresist based on the fluorescent light.

A white light illumination source can illuminate a region of a substrate to be plasma etched with an incident light beam. A camera takes successive images of the region being illuminated during a plasma etch process. Image processing techniques can be applied to the images so as to identify a location of at least one feature on the substrate and to measure a reflectivity signal at the location. The plasma etch process can be modified in response to the measured reflectivity signal at the location.

A method for inspecting a sample by means of a multi-beam charged particle inspection apparatus, and an apparatus for performing this method are provided. The multi-beam charged particle inspection apparatus is configured to project an array of charged particle beamlets within an exposure area on the sample. The apparatus includes a detection system for detecting X-Rays and/or cathodoluminescent light from the exposure area emitted by the sample due to an interaction of the array of charged particle beamlets with the sample. The method includes the steps of projecting the array of charged particle beamlets within the exposure area on the sample, and monitoring a combined emission of X-Rays and/or cathodoluminescent light from the interaction of substantially all charged particle beamlets of the array of charged particle beamlets with the sample.

A specimen machining device includes an illumination system that illuminates a specimen; a camera that photographs the specimen; and a processing unit that controls the illumination system and the camera, and acquires a machining control image which is used for controlling an ion source and a display image which is displayed on a display unit. The processing unit controls the illumination system to illuminate the specimen under a machining illumination condition; acquires the machining control image by controlling the camera to photograph the specimen illuminated under the machining control illumination condition; controls the ion source based on the machining control image; controls the illumination system to illuminate the specimen under a display illumination condition which is different from the machining control illumination condition; acquires the display image by controlling the camera to photograph the specimen illuminated under the display illumination condition; and displays the display image on the display unit.

An optical height detection system in a charged particle beam inspection system. The optical height detection system includes a projection unit including a modulated illumination source, a projection grating mask including a projection grating pattern, and a projection optical unit for projecting the projection grating pattern to a sample; and a detection unit including a first detection grating mask including a first detection grating pattern, a second detection grating mask including a second detection grating pattern, and a detection optical system for forming a first grating image from the projection grating pattern onto the first detection grating mask and forming a second grating image from the projection grating pattern onto the second detection grating masks. The first and second detection grating patterns at least partially overlap the first and second grating images, respectively.

An apparatus for and a method of inspecting a substrate in which a charged particle beam is arranged to impinge on a portion of the substrate and a first light beam having a first wavelength and a second light beam having a second wavelength different from the first wavelength are also arranged to impinge on the portion of the substrate.

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.

An object of the invention is to provide a charged particle beam device capable of specifying an irradiation position of light on a sample when there is no mechanism for forming an image of backscattered electrons. The charged particle beam device according to the invention determines whether an irradiation position of a primary charged particle beam and an irradiation position of light match based on a difference between a first observation image acquired when the sample is irradiated with only the primary charged particle beam and a second observation image acquired when sample is irradiated with the light in addition to the primary charged particle beam. It is determined whether the irradiation position of the primary charged particle beam and the irradiation position of the light match using the first observation image and a measurement result by a light amount measuring device.

A system and method for advanced charge control of a light beam is provided. The system comprising a laser source comprising a laser diode for emitting a beam and a beam homogenizer to homogenize the emitted beam. The system and methods further comprise a beam shaper configured to shape the emitted beam using an anamorphic prism group and a driver configured to direct the shaped beam to a specified position on a wafer, wherein the laser source, the beam shaper, and the driver are coaxially aligned.

A contamination prevention irradiation device includes a generation unit and a mirror unit. The generation unit generates a laser beam. The mirror unit has a mirror surface for reflecting a laser beam. The laser beam reflected on the mirror surface is applied to a specimen disposed inside an objective lens. The laser beam is composed of a pulse train. Once a laser beam is applied to the specimen before observation of the specimen, deposition of contaminants on the specimen can be prevented for a predetermined subsequent period.