Systems and methods for implementing charged particle flooding in a charged particle beam apparatus are disclosed. According to certain embodiments, a charged particle beam system includes a charged particle source and a controller which controls the charged particle beam system to emit a charged particle beam in a first mode where the beam is defocused and a second mode where the beam is focused on a surface of a sample.

The present disclosure relates to a collimator. The collimator may include a motor, a transmission unit having a first end and a second end, and a leaf unit having a leaf. The first end of the transmission unit may be connected to the motor and the second end of the transmission unit may be connected to the leaf. The present disclosure also relates to a collimator system. The collimator system may include a leaf module having a leaf, a driving module having a motor configured to drive the leaf, and a processing module to generate a movement profile of the leaf. The movement profile of the leaf may include a first speed during a first stage, a second speed of the leaf during a second stage, and a third speed of the leaf during a third stage.

A charged particle beam apparatus includes a sample chamber; a sample stage; an electron beam column for irradiating a sample with an electron beam; and a focused ion beam column for irradiating the sample with a focused ion beam. The apparatus includes a displacement member having an open/close portion displaceable between an insertion position between a beam emitting end portion of the electron beam column and the sample stage, and a withdrawal position away from the insertion position, and a contact portion provided at a contact position capable of contacting the sample before the beam emitting end portion during operation of the sample stage. A driving unit displaces the displacement member, and a conduction sensor detects whether the sample is in contact with the contact portion.

A multi-beam charged particle system and a method of operating a multi-beam charged particle system can provide improved image contrast. The multi-beam charged particle system comprises a filter element or an active array element in a detection system, which can provide improved, anisotropic image contrast. The disclosure can be applied for applications of multi-beam charged particle system, where higher requirements on beam uniformity and throughput may be relevant.

In one embodiment, a multi charged particle beam drawing apparatus includes an emitter emitting a charged particle beam, a shaping aperture array in which a plurality of first openings are formed, and which receives irradiation of the charged particle beam in an area including the plurality of first openings, and forms a multi-beam by allowing part of the charged particle beam to pass through a corresponding one of the plurality of first openings, a blanking aperture array in which a plurality of second openings are formed, through each of which a beam is passed, corresponding to part of the multi-beam which has passed through the plurality of first openings, the plurality of second openings each including a blanker that performs blanking deflection of a beam, and a movement controller moving the shaping aperture array or the blanking aperture array, and adjusting space between the shaping aperture array and the blanking aperture array.

A system and method for optimizing a ribbon ion beam in a beam line implantation system is disclosed. The system includes a mass resolving apparatus having a resolving aperture, in which the resolving aperture may be moved in the X and Z directions. Additionally, a controller is able to manipulate the mass analyzer and quadrupole lenses so that the crossover point of desired ions can also be moved in the X and Z directions. By manipulating the crossover point and the resolving aperture, the parameters of the ribbon ion beam may be manipulated to achieve a desired result. Movement of the crossover point in the X direction may affect the mean horizontal angle of the beamlets, while movement of the crossover point in the Z direction may affect the horizontal angular spread and beam current.

An example of a sputtering apparatus comprises a first target and a second target that emit sputter particles, a substrate support configured to support a substrate, a shielding plate disposed between the first and the second target and the substrate and having a through-hole through which the sputter particles pass, and an obstructing mechanism. The through-hole has a first opening region through which the sputter particles emitted from the fit target pass and a second opening region through which the sputter particles emitted from the second target pass, and the obstructing mechanism is configured to obstruct the sputter particles emitted from the first target in passing through the second opening region and the sputter particles emitted in the second target from passing through the first opening region.

Particle beam systems, for example electron beam microscopes, exhibit improved resolution in a first direction by manipulating a beam of charged particles so that the beam has a non-circular beam profile in a focal plane of an objective lens. Multiple images of a sample can be recorded at different orientations of the beam profile relative to the sample, and the recorded images can be synthesized using non-uniform spatial-frequency weights to obtain an image of the sample having improved resolution in any direction. The orientation of the beam profile can be adjusted to a target orientation depending on a structure on a sample prior to recording an image of the sample, thereby making it possible to achieve highest resolution in a selected direction of interest.

A multi-beam optical system adjustment method includes forming multi-beams by making a region including the whole of a plurality of openings in a shaping aperture array substrate irradiated by a charged particle beam, and making portions of the charged particle beam individually pass through a corresponding one of the plurality of openings, measuring a distortion of the multi-beams while variably changing the crossover height position of the multi-beams, measuring the crossover height position of the multi-beams where the distortion of the multi-beams is smaller than the others, and adjusting the height position of a limiting aperture substrate which limits passage of a beam deviated from the trajectory in the multi-beams to the crossover height position.

The present disclosure provides a charged particle beam device. The charged particle beam device includes a charged particle source configured to emit a charged particle beam, a condenser lens arrangement, an aperture arrangement configured to generate two or more beamlets of the charged particle beam, wherein the aperture arrangement includes a plurality of first openings and a plurality of second openings different from the plurality of second openings, and a multipole arrangement configured to act on the two or more beamlets. The aperture arrangement is configured to align the plurality of first openings or the plurality of second openings with the multipole arrangement.