Abstract: A system inspects, modifies or analyzes a region of interest of a sample via charged particles. A detector device of the system produces a pixel image having horizontal and vertical pixel resolutions. A charged particle deflection device produces a scanning charged particle beam in a scanning region. The deflection device has horizontal and vertical deflection units controlled by a digital to analog converter having a digital resolution larger than the horizontal pixel resolution and/or the vertical pixel resolution. An operator control interface of the system selects an assignment between respective image pixels of a desired pixel image and digital inputs of the DAC to produce horizontal and/or vertical deflection signals to guide the charged particle beam to the location of the respective image pixel. A reliable image of a sample can be obtained even when there is zooming or panning within an accessible region of the sample.

Abstract: The present disclosure relates to a charged particle beam system comprising a charged particle beam source, a charged particle column, a sample chamber, a plurality of electrically powered devices arranged within or at either one of the charged particle column, the charged particle beam source and the sample chamber, and at least one first converter to convert an electrical AC voltage power into an electrical DC voltage. The first converter is positioned at a distance from either of the charged particle beam source, the charged particle column and the charged particle chamber, and all elements of the plurality of electrically powered devices, when operated during operation of the charged particle beam source, are configured to be exclusively powered by the DC voltage provided by the converter.

Abstract: The present disclosure relates to a charged particle beam system, comprising a noble gas field ion beam source, a charged particle beam column, and a housing defining a first vacuum region and a second vacuum region. A noble gas field ion beam source is arranged within the first vacuum region. A first mechanical vacuum pump is functionally attached to the first vacuum region, an ion getter pump is attached to the charged particle beam column, and a gas supply is attached to the first vacuum region configured to supply a noble gas to the noble gas field ion beam source.

Abstract: Systems and methods for heating an apex of a tip of a charged particle source are disclosed. The charged particle source can be, for example, a gas ion source. The systems can include a detector configured to detect light generated by the tip apex, and a controller coupled with the charged particle source and the detector so that the controller can control heating of the tip apex based on the light detected by the detector.

Abstract: The present disclosure relates to a charged particle beam system comprising a charged particle beam source, a charged particle column, a sample chamber, a plurality of electrically powered devices arranged within or at either one of the charged particle column, the charged particle beam source and the sample chamber, and at least one first converter to convert an electrical AC voltage power into an electrical DC voltage. The first converter is positioned at a distance from either of the charged particle beam source, the charged particle column and the charged particle chamber, and all elements of the plurality of electrically powered devices, when operated during operation of the charged particle beam source, are configured to be exclusively powered by the DC voltage provided by the converter.

Abstract: The present disclosure relates to a charged particle beam system, comprising a noble gas field ion beam source, a charged particle beam column, and a housing defining a first vacuum region and a second vacuum region. A noble gas field ion beam source is arranged within the first vacuum region. A first mechanical vacuum pump is functionally attached to the first vacuum region, an ion getter pump is attached to the charged particle beam column, and a gas supply is attached to the first vacuum region configured to supply a noble gas to the noble gas field ion beam source.

Abstract: Ion sources, systems and methods are disclosed. In some embodiments, the ion sources, systems and methods can exhibit relatively little undesired vibration and/or can sufficiently dampen undesired vibration. This can enhance performance (e.g., increase reliability, stability and the like).

Abstract: Cooled charged particle sources and methods are disclosed. In some embodiments, a charged particle source is thermally coupled to a solid cryogen, such as solid nitrogen. The thermal coupling can be design to provide good thermal conductivity to maintain the charged particle source at a desirably low temperature.

Abstract: Ion sources, systems and methods are disclosed. In some embodiments, the ion sources, systems and methods can exhibit relatively little undesired vibration and/or can sufficiently dampen undesired vibration. This can enhance performance (e.g., increase reliability, stability and the like).

Abstract: Systems and methods for heating an apex of a tip of a charged particle source are disclosed. The charged particle source can be, for example, a gas ion source. The systems can include a detector configured to detect light generated by the tip apex, and a controller coupled with the charged particle source and the detector so that the controller can control heating of the tip apex based on the light detected by the detector.