A charged particle beam device includes: a charged particle source that emits a charged particle beam; a boosting electrode disposed between the charged particle source and a sample to form a path of the charged particle beam and to accelerate and decelerate the charged particle beam; a first pole piece that covers the boosting electrode; a second pole piece that covers the first pole piece; a first lens coil disposed outside the first pole piece and inside the second pole piece to form a first lens; a second lens coil disposed outside the second pole piece to form a second lens; and a control electrode formed between a distal end portion of the first pole piece and a distal end portion of the second pole piece to control an electric field formed between the sample and the distal end portion of the second pole piece.

Variable multi-beam charged particle devices for inspection of a sample include a multi-beam source that produces a plurality of charged particle beamlets, an objective lens, a sample holder for holding the sample between the objective lens and the multi-beam source, and a focusing column that directs the plurality of charged particle beamlets so that they are incident upon the sample. The focusing column directs the plurality of charged beams such that there are one or more crossovers of the plurality of charged particle beamlets, where each crossover corresponds to a point where the plurality of charged particle beamlets pass through a common location. The variable multi-beam charged particle devices also include a variable aperture that is configured to vary the current of the plurality of charged particle beamlets, and which is located at a final crossover of the one or more crossovers that is most proximate to the sample.

A multi-beam apparatus for observing a sample with high resolution and high throughput and in flexibly varying observing conditions is proposed. The apparatus uses a movable collimating lens to flexibly vary the currents of the plural probe spots without influencing the intervals thereof, a new source-conversion unit to form the plural images of the single electron source and compensate off-axis aberrations of the plural probe spots with respect to observing conditions, and a pre-beamlet-forming means to reduce the strong Coulomb effect due to the primary-electron beam.

A multiple electron beam irradiation apparatus includes a forming mechanism which forms multiple primary electron beams; a plurality of electrode substrates being stacked in each of which a plurality of openings of various diameter dimensions are formed, the plurality of openings being arranged at passage positions of the multiple primary electron beams, and through each of which a corresponding one of the multiple primary electron beams passes, the plurality of electrode substrates being able to adjust an image plane conjugate position of each of the multiple primary electron beams depending on a corresponding one of the various diameter dimensions; and a stage which is capable of mounting thereon a target object to be irradiated with the multiple primary electron beams having passed through the plurality of electrode substrates.

The present invention provides apparatuses to inspect small particles on the surface of a sample such as wafer and mask. The apparatuses provide both high detection efficiency and high throughput by forming Dark-field BSE images. The apparatuses can additionally inspect physical and electrical defects on the sample surface by form SE images and Bright-field BSE images simultaneously. The apparatuses can be designed to do single-beam or even multiple single-beam inspection for achieving a high throughput.

An objective lens arrangement includes a first, second and third pole pieces, each being substantially rotationally symmetric. The first, second and third pole pieces are disposed on a same side of an object plane. An end of the first pole piece is separated from an end of the second pole piece to form a first gap, and an end of the third pole piece is separated from an end of the second pole piece to form a second gap. A first excitation coil generates a focusing magnetic field in the first gap, and a second excitation coil generates a compensating magnetic field in the second gap. First and second power supplies supply current to the first and second excitation coils, respectively. A magnetic flux generated in the second pole piece is oriented in a same direction as a magnetic flux generated in the second pole piece.

An immersion objective lens is configured below a stage such that multiple detectors can be configured above sample for large beam current application, particularly for defect inspection. Central pole piece of the immersion objective lens thus can be provided that a magnetic monopole-like field can be provided for electron beam. Auger electron detector thus can be configured to analyze materials of sample in the defect inspection.

An apparatus for generating a multiplicity of particle beams includes a particle source, a first multi-aperture plate with a multiplicity of openings, a second multi-aperture plate with a multiplicity of openings, a first particle lens, a second particle lens, a third particle lens 23, and a controller, which supplies each of the first particle lens, the second particle lens and the third particle lens with an adjustable excitation.

A multi-beam apparatus for observing a sample with high resolution and high throughput and in flexibly varying observing conditions is proposed. The apparatus uses a movable collimating lens to flexibly vary the currents of the plural probe spots without influencing the intervals thereof, a new source-conversion unit to form the plural images of the single electron source and compensate off-axis aberrations of the plural probe spots with respect to observing conditions, and a pre-beamlet-forming means to reduce the strong Coulomb effect due to the primary-electron beam.

An objective lens arrangement includes a first, second and third pole pieces, each being substantially rotationally symmetric. The first, second and third pole pieces are disposed on a same side of an object plane. An end of the first pole piece is separated from an end of the second pole piece to form a first gap, and an end of the third pole piece is separated from an end of the second pole piece to form a second gap. A first excitation coil generates a focusing magnetic field in the first gap, and a second excitation coil generates a compensating magnetic field in the second gap. First and second power supplies supply current to the first and second excitation coils, respectively. A magnetic flux generated in the second pole piece is oriented in a same direction as a magnetic flux generated in the second pole piece.