A gas feed device is operated, including displaying a functional parameter of the gas feed device. A gas feed device may carry out the operation, and a particle beam apparatus may include the gas feed device. A method may include predetermining and/or measuring a current temperature of a precursor reservoir of the gas feed device using a temperature measuring unit, where the precursor reservoir contains a precursor to be fed onto an object, loading a flow rate of the precursor through an outlet of the precursor reservoir from a database into a control unit, said flow rate being associated with the current temperature of the precursor reservoir, and (i) displaying the flow rate on the display unit and/or (ii) determining the functional parameter of the precursor reservoir depending on the flow rate using the control unit and informing a user of the gas feed device about the determined functional parameter.

A gas feed device is operated, including displaying a functional parameter of the gas feed device. A gas feed device may carry out the operation, and a particle beam apparatus may include the gas feed device. A method may include predetermining and/or measuring a current temperature of a precursor reservoir of the gas feed device using a temperature measuring unit, where the precursor reservoir contains a precursor to be fed onto an object, loading a flow rate of the precursor through an outlet of the precursor reservoir from a database into a control unit, said flow rate being associated with the current temperature of the precursor reservoir, and (i) displaying the flow rate on the display unit and/or (ii) determining the functional parameter of the precursor reservoir depending on the flow rate using the control unit and informing a user of the gas feed device about the determined functional parameter.

A multi-beam inspection apparatus supporting a plurality of operation modes is disclosed. The charged particle beam apparatus for inspecting a sample supporting a plurality of operation modes comprises a charged particle beam source configured to emit a charged particle beam along a primary optical axis, a movable aperture plate, movable between a first position and a second position, and a controller having circuitry and configured to change the configuration of the apparatus to switch between a first mode and a second mode. In the first mode, the movable aperture plate is positioned in the first position and is configured to allow a first charged particle beamlet derived from the charged particle beam to pass through. In the second mode, the movable aperture plate is positioned in the second position and is configured to allow the first charged particle beamlet and a second charged particle beamlet to pass through.

A multi-beam inspection apparatus supporting a plurality of operation modes is disclosed. The charged particle beam apparatus for inspecting a sample supporting a plurality of operation modes comprises a charged particle beam source configured to emit a charged particle beam along a primary optical axis, a movable aperture plate, movable between a first position and a second position, and a controller having circuitry and configured to change the configuration of the apparatus to switch between a first mode and a second mode. In the first mode, the movable aperture plate is positioned in the first position and is configured to allow a first charged particle beamlet derived from the charged particle beam to pass through. In the second mode, the movable aperture plate is positioned in the second position and is configured to allow the first charged particle beamlet and a second charged particle beamlet to pass through.

A low voltage scanning electron microscope is disclosed, which includes: an electron source configured to generate an electron beam; an electron beam accelerator configured to accelerate the electron beam; a compound objective lens configured to converge the electron beams accelerated by the electron beam accelerator; a deflection device arranged between the inner wall of the magnetic lens and the optical axis of the electron beam and configured to deflect the electron beam; a detection device comprising a first sub-detection device for receiving secondary and backscattered electrons from the specimen, a second sub-detection device for receiving backscattered electrons, and a control device for changing the trajectories of the secondary electrons and the backscattered electrons; an electrostatic lens comprising the second sub-detection device, a specimen stage, and a control electrode for reducing the moving speed of the electron beam and changing the moving directions of the secondary and the backscattered electrons.

A low voltage scanning electron microscope is disclosed, which includes: an electron source configured to generate an electron beam; an electron beam accelerator configured to accelerate the electron beam; a compound objective lens configured to converge the electron beams accelerated by the electron beam accelerator; a deflection device arranged between the inner wall of the magnetic lens and the optical axis of the electron beam and configured to deflect the electron beam; a detection device comprising a first sub-detection device for receiving secondary and backscattered electrons from the specimen, a second sub-detection device for receiving backscattered electrons, and a control device for changing the trajectories of the secondary electrons and the backscattered electrons; an electrostatic lens comprising the second sub-detection device, a specimen stage, and a control electrode for reducing the moving speed of the electron beam and changing the moving directions of the secondary and the backscattered electrons.

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.

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 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.

A low voltage scanning electron microscope is disclosed, which includes: an electron source configured to generate an electron beam; an electron beam accelerator configured to accelerate the electron beam; a compound objective lens configured to converge the electron beams accelerated by the electron beam accelerator; a deflection device arranged between the inner wall of the magnetic lens and the optical axis of the electron beam and configured to deflect the electron beam; a detection device comprising a first sub-detection device for receiving secondary and backscattered electrons from the specimen, a second sub-detection device for receiving backscattered electrons, and a control device for changing the trajectories of the secondary electrons and the backscattered electrons; an electrostatic lens comprising the second sub-detection device, a specimen stage, and a control electrode for reducing the moving speed of the electron beam and changing the moving directions of the secondary and the backscattered electrons.