Abstract: An e-beam device includes a cold-field emission source to emit electrons and an extractor electrode to be positively biased with respect to the cold-field emission source to extract the electrons from the cold-field emission source. The extractor electrode has a first opening for the electrons. The e-beam device also includes a mirror electrode with a second opening for the electrons. The mirror electrode is configurable to be positively biased with respect to the extractor electrode during a first mode of operation and to be negatively biased with respect to the extractor electrode during a second mode of operation. The extractor electrode is disposed between the cold-field emission source and the mirror electrode. The e-beam device further includes an anode to be positively biased with respect to the extractor electrode and the cold-field emission source. The mirror electrode is disposed between the extractor electrode and the anode.

Abstract: An e-beam device includes a cold-field emission source to emit electrons and an extractor electrode to be positively biased with respect to the cold-field emission source to extract the electrons from the cold-field emission source. The extractor electrode has a first opening for the electrons. The e-beam device also includes a mirror electrode with a second opening for the electrons. The mirror electrode is configurable to be positively biased with respect to the extractor electrode during a first mode of operation and to be negatively biased with respect to the extractor electrode during a second mode of operation. The extractor electrode is disposed between the cold-field emission source and the mirror electrode. The e-beam device further includes an anode to be positively biased with respect to the extractor electrode and the cold-field emission source. The mirror electrode is disposed between the extractor electrode and the anode.

Abstract: An electron source emits an electron beam. The electron beam is received by a beam limiting assembly. The beam limiting assembly has a first beam limiting aperture with a first diameter and a second beam limiting aperture with a second diameter larger than the first diameter. The first beam limiting aperture receives the electron beam. This beam limiting assembly reduces the influence of Coulomb interactions.

Abstract: An electron source emits an electron beam. The electron beam is received by a beam limiting assembly. The beam limiting assembly has a first beam limiting aperture with a first diameter and a second beam limiting aperture with a second diameter larger than the first diameter. The first beam limiting aperture receives the electron beam. This beam limiting assembly reduces the influence of Coulomb interactions.

Abstract: An electron source is disclosed. The electron source may include an electron emitter configured to generate one or more electron beams. The electron source may further include a magnetic suppressor electrode surrounding at least a portion of the electron emitter. The magnetic suppressor electrode may be formed from one or more magnetic materials. The magnetic suppressor may be configured to shield at least a portion of the electron emitter from an axial magnetic field. The electron source may further include an extractor electrode positioned adjacent to a tip of the electron emitter.

Abstract: A high-resolution electron energy analyzer is disclosed. In one embodiment, the electron energy analyzer includes an electrostatic lens configured to generate an energy-analyzing field region, decelerate electrons of an electron beam generated by an electron source, and direct the decelerated electrons of the electron beam to the energy-analyzing field region. In another embodiment, the electron energy analyzer includes an electron detector configured to receive one or more electrons passed through the energy-analyzing field region. In another embodiment, the electron detector is further configured to generate one or more signals based on the one or more received electrons.

Abstract: A high-resolution electron energy analyzer is disclosed. In one embodiment, the electron energy analyzer includes an electrostatic lens configured to generate an energy-analyzing field region, decelerate electrons of an electron beam generated by an electron source, and direct the decelerated electrons of the electron beam to the energy-analyzing field region. In another embodiment, the electron energy analyzer includes an electron detector configured to receive one or more electrons passed through the energy-analyzing field region. In another embodiment, the electron detector is further configured to generate one or more signals based on the one or more received electrons.

Abstract: Extractors and extractor systems minimize the generation of secondary electrons which interact with and degrade the primary electron beam. This can improve the performance of an electron beam system, such as a scanning electron microscope. The extractor may include a frustoconical aperture that widens as distance from the source of the electron beam increases. The entrance into the frustoconical aperture also can include a curved edge.

Abstract: A cathodoluminescent mosaic screen on a light-transparent substrate wherein the light-emitting components of the screen are implemented as light-guiding single-crystalline columns. A method for preparation of the screen by vapor deposition of the luminescent material onto the substrate coated by a localized liquid phase has been proposed.