The scanning electron microscope includes: an electron source; a first deflector for deflecting a primary electron beam emitted from the electron source; a second deflector for focusing the primary electron beam deflected by the first deflector and deflecting a second electron from a sample, which is generated the focused primary electron beam, to the outside of the optical axis; a voltage applying unit for applying a negative voltage to the sample to decelerate the primary electron beam; a spectrometer for dispersing the secondary electron; a detector for detecting the secondary electron passing through the spectrometer; an electrostatic lens provided between the second deflector and the spectrometer; and a voltage control unit that controls the voltage applied to the electrostatic lens based on the negative voltage applied to the sample. The electrostatic lens allows the deflecting action to be overlapped with the converging action.

A method is provided for processing and/or observing an object using at least one particle beam that is scanned over the object. A scan region on the object is determined, the scan region having scan lines, and the particle beam is moved in a first scanning direction along one of the scan lines. The first scanning direction is changed to a second scanning direction at a change-of-direction time. Changing from the first scanning direction to the second scanning direction comprises setting of a point of rotation in that scan line of the scan region in which the particle beam is situated at the change-of-direction time, with an axis of rotation extending through the point of rotation. The first scanning direction is changed into the second scanning direction by rotating the scan region about the axis of rotation, with the point of rotation being selected dependent on the direction of rotation.

A method and a system for imaging an object, the system may include electron optics that may be configured to scan a first area of the object with at least one electron beam; wherein the electron optics may include a first electrode; and light optics that may be configured to illuminate at least one target of (a) the first electrode and (b) the object, thereby causing an emission of electrons between the first electrode and the object.

A specimen loading method for loading a specimen that contains water into a specimen chamber of a charged particle beam device, includes: a step (S100) of mounting the specimen on a specimen support; a step (S102) of covering a predetermined area of the specimen with a water retention material; a step (S104) of evacuating the specimen chamber in which the specimen having the predetermined area covered with the water retention material is placed; and a step (S106) of exposing the predetermined area covered with the water retention material.

A method includes: generating a multiplicity of particle beams such that the particle beams penetrate a predetermined plane side-by-side and have within a volume region around the predetermined plane in each case one beam focus; scanning a first region of the surface of an object with the particle beams and detecting first intensities of particles produced by the particle beams while setting an operating parameter of the multi-beam particle microscope; and determining first values of an object property based on the first intensities. The first values represent the object property within the first region, and the object property represents a physical property of the object. The method also includes determining a second value of the operating parameter for use for a second region of the surface based on the first values of the object property.

Charged particle beam imaging and measurement systems are provided using gas amplification with an improved imaging gas. The system includes a charged particle beam source for directing a charged particle beam to work piece, a focusing lens for focusing the charged particles onto the work piece, and an electrode for accelerating secondary electrons generated from the work piece irradiation by the charged practice beam, or another gas cascade detection scheme. The gas imaging is performed in a high pressure scanning electron microscope (HPSEM) chamber for enclosing the improved imaging gas including CH.sub.3CH.sub.2OH (ethanol) vapor. The electrode accelerates the secondary electrons though the CH.sub.3CH.sub.2OH to ionize the CH.sub.3CH.sub.2OH through ionization cascade to amplify the number of secondary electrons for detection. An optimal configuration is provided for use of the improved imaging gas, and techniques are provided to conduct imaging studies of organic liquids and solvents, and other CH.sub.3CH.sub.2OH-based processes.

An electron beam apparatus (100) is described, including an electron source (105) configured to generate a primary electron beam propagating along an optical axis (A), a sample stage (108) configured to support a sample, an objective lens (120) configured to focus the primary electron beam on the sample for causing an emission of a signal electron beam and a foil or grid lens (300, 400) for influencing the signal electron beam. The foil or grid lens includes an electrode (340) that surrounds the optical axis; and a first foil or grid (320) adjacent to the electrode and perpendicular to the optical axis, the first foil or grid being substantially transparent to electrons, wherein a central opening (325) configured to allow the primary electron beam to pass through the central opening is provided in the first foil or grid.

Systems directed to a stage apparatus in an electron beam inspection tool to inspect a sample are disclosed. The stage apparatus comprises a short stroke stage; a long stroke stage; a first sensor configured to measure a position of the short stroke stage with respect to a measurement reference; one or more roller bearings configured to support the long stroke stage; and a controller having circuitry and configured to control a motion of the long stroke stage and a motion of the short stroke stage for following movement of the reference at least partly based on measurement from the first sensor, wherein the controller is operable such that control of the long stroke stage is decoupled from the movement of the reference in at least a part of operation of the stage apparatus for reducing debris generation of the one or more roller bearings.

A scanning electron microscope (SEM) with a swing objective lens (SOL) reduces the off-aberrations to enhance the image resolution, and extends the e-beam scanning angle. The scanning electron microscope comprises a charged particle source, an accelerating electrode, and a swing objective lens system including a pre-deflection unit, a swing deflection unit and an objective lens, all of them are rotationally symmetric with respect to an optical axis. The upper inner-face of the swing deflection unit is tilted an angle to the outer of the SEM and its lower inner-face is parallel to the optical axis. A distribution for a first and second focusing field of the swing objective lens is provided to limit the off-aberrations and can be performed by a single swing deflection unit. Preferably, the two focusing fields are overlapped by each other at least 80 percent.

The purpose of the present invention is to provide a charged particle gun using merely an electrostatic lens, said charged particle gun being relatively small and having less aberration, and to provide a field emission-type charged particle gun having high luminance even with a high current. This charged particle gun has: a charged particle source; an acceleration electrode that accelerates charged particles emitted from the charged particle source; a control electrode, which is disposed further toward the charged particle source side than the acceleration electrode, and which has a larger aperture diameter than the aperture diameter of the acceleration electrode; and a control unit that controls, on the basis of a potential applied to the acceleration electrode, a potential to be applied to the control electrode.