Methods for using a single electron microscope system for investigating a sample with TEM and STEM techniques include the steps of emitting electrons toward the sample, forming the electrons into a two beams, and then modifying the focal properties of at least one of the two beams such that they have different focal planes. Once the two beams have different focal planes, the first electron beam is focused such that it acts as a STEM beam that is focused at the sample, and the second electron beam is focused so that it acts as a TEM beam that is parallel beam when incident on the sample. Emissions resultant from the STEM beam and the TEM beam being incident on the sample can then be detected by a single detector or detector array and used to generate a TEM image and a STEM image.

The present invention addresses the problem of providing an electron beam generator and an electron beam applicator for which maintenance is facilitated. The electron beam generator comprises a vacuum chamber, a photocathode holder, an activation vessel, and an internal motive power transmission member. The photocathode holder is capable of moving relative to the activation vessel.

A multiple electron beam irradiation apparatus includes a shaping aperture array substrate to form multiple primary electron beams, a plurality of electrode array substrates stacked each to dispose thereon a plurality of electrodes each arranged at a passage position of each of the multiple primary electron beams, each of the multiple primary electron beams surrounded by an electrode of the plurality of electrodes when each of the multiple primary electron beams passes through the passage position, the first wiring and the second wiring applied with one of different electric potentials, and a stage to mount thereon a target object to be irradiated with the multiple primary electron beams having passed through the plurality of electrode array substrates, wherein, in each of the plurality of electrode array substrates, each of the plurality of electrodes is electrically connected to either one of the first wiring and the second wiring.

A particle beam apparatus includes a first aperture unit having an adjustable aperture opening. The particle beam apparatus may include a first condenser lens having a first pole shoe and a second pole shoe. Both the first pole shoe and the second pole shoe may be adjustable relative to a second aperture unit independently of each other. The second aperture unit may be designed as a pressure stage aperture separating a first area having a vacuum at a first pressure, and a second area having a vacuum at a second pressure. Additionally, a method for adjusting a beam current in a particle beam apparatus is provided.

A particle beam apparatus includes a first aperture unit having an adjustable aperture opening. The particle beam apparatus may include a first condenser lens having a first pole shoe and a second pole shoe. Both the first pole shoe and the second pole shoe may be adjustable relative to a second aperture unit independently of each other. The second aperture unit may be designed as a pressure stage aperture separating a first area having a vacuum at a first pressure, and a second area having a vacuum at a second pressure. Additionally, a method for adjusting a beam current in a particle beam apparatus is provided.

An electron beam inspection apparatus, the apparatus including a plurality of electron beam columns, each electron beam column configured to provide an electron beam and detect scattered or secondary electrons from an object, and an actuator system configured to move one or more of the electron beam columns relative to another one or more of the electron beam columns. The actuator system may include a plurality of first movable structures at least partly overlapping a plurality of second movable structures, the first and second movable structures supporting the plurality of electron beam columns.

An electron beam inspection apparatus, the apparatus including a plurality of electron beam columns, each electron beam column configured to provide an electron beam and detect scattered or secondary electrons from an object, and an actuator system configured to move one or more of the electron beam columns relative to another one or more of the electron beam columns. The actuator system may include a plurality of first movable structures at least partly overlapping a plurality of second movable structures, the first and second movable structures supporting the plurality of electron beam columns.

A charged particle beam device is provided in which axis adjustment as a superimposing lens is facilitated by aligning an axis of an electrostatic lens resulting from a deceleration electric field with an axis of a magnetic field lens. The charged particle beam device includes: an electron source; an objective lens that focuses a probe electron beam from the electron source on a sample; a first beam tube and a second beam tube through each of which the probe electron beam passes; a deceleration electrode arranged between the first beam tube and a sample; a first voltage source that forms a deceleration electric field for the probe electron beam between the first beam tube and the deceleration electrode by applying a first potential to the first beam tube; and a first moving mechanism that moves a position of the first beam tube.

A charged particle beam device is provided in which axis adjustment as a superimposing lens is facilitated by aligning an axis of an electrostatic lens resulting from a deceleration electric field with an axis of a magnetic field lens. The charged particle beam device includes: an electron source; an objective lens that focuses a probe electron beam from the electron source on a sample; a first beam tube and a second beam tube through each of which the probe electron beam passes; a deceleration electrode arranged between the first beam tube and a sample; a first voltage source that forms a deceleration electric field for the probe electron beam between the first beam tube and the deceleration electrode by applying a first potential to the first beam tube; and a first moving mechanism that moves a position of the first beam tube.

An ion source includes a plasma chamber, and a suppression electrode disposed downstream of the plasma chamber, and is operable to irradiate the suppression electrode with an ion beam produced from a cleaning gas to clean the suppression electrode. Prior to cleaning, the ion source moves the suppression electrode or the plasma chamber in a first direction to increase a distance between the plasma chamber and the suppression electrode.