Abstract: An apparatus, system and method of using electrons to perform at least one operation are disclosed. An apparatus may include groups of carbon nanotubes capable of emitting a relatively large number of electrons for use in performing operations such as sterilization, purification, deodorization, cleaning, cross-linking, pest control, pathogen control, chain-scissioning associated with surface modification, waste treatment, etc. Each group of carbon nanotubes may be aligned with a respective opening in a member, where the member may be coupled with a membrane capable of transmitting electrons. Electrons may be emitted from the carbon nanotubes by applying a vacuum to the carbon nanotubes and also applying an electric potential between the carbon nanotubes and the member. As such, electrons from a plurality of groups of carbon nanotubes may generate an electron flow that can be used to perform one or more operations on a fluid, object, or other type of component.

Abstract: An electron gun, an electron source for an electron gun, an extractor for an electron gun, and a respective method for producing the electron gun, the electron source and the extractor are disclosed. Embodiments provide an electron source utilizing a carbon nanotube (CNT) bonded to a substrate for increased stability, reliability, and durability. An extractor with an aperture in a conductive material is used to extract electrons from the electron source, where the aperture may substantially align with the CNT of the electron source when the extractor and electron source are mated to form the electron gun. The electron source and extractor may have alignment features for aligning the electron source and the extractor, thereby bringing the aperture and CNT into substantial alignment when assembled. The alignment features may provide and maintain this alignment during operation to improve the field emission characteristics and overall system stability of the electron gun.

Abstract: An apparatus, system and method of using electrons to perform at least one operation are disclosed. An apparatus may include groups of carbon nanotubes capable of emitting a relatively large number of electrons for use in performing operations such as sterilization, purification, deodorization, cleaning, cross-linking, pest control, pathogen control, chain-scissioning associated with surface modification, waste treatment, etc. Each group of carbon nanotubes may be aligned with a respective opening in a member, where the member may be coupled with a membrane capable of transmitting electrons. Electrons may be emitted from the carbon nanotubes by applying a vacuum to the carbon nanotubes and also applying an electric potential between the carbon nanotubes and the member. As such, electrons from a plurality of groups of carbon nanotubes may generate an electron flow that can be used to perform one or more operations on a fluid, object, or other type of component.

Abstract: An electron gun, an electron source for an electron gun, an extractor for an electron gun, and a respective method for producing the electron gun, the electron source and the extractor are disclosed. Embodiments provide an electron source utilizing a carbon nanotube (CNT) bonded to a substrate for increased stability, reliability, and durability. An extractor with an aperture in a conductive material is used to extract electrons from the electron source, where the aperture may substantially align with the CNT of the electron source when the extractor and electron source are mated to form the electron gun. The electron source and extractor may have alignment features for aligning the electron source and the extractor, thereby bringing the aperture and CNT into substantial alignment when assembled. The alignment features may provide and maintain this alignment during operation to improve the field emission characteristics and overall system stability of the electron gun.

Abstract: An electron gun, an electron source for an electron gun, an extractor for an electron gun, and a respective method for producing the electron gun, the electron source and the extractor are disclosed. Embodiments provide an electron source utilizing a carbon nanotube (CNT) bonded to a substrate for increased stability, reliability, and durability. An extractor with an aperture in a conductive material is used to extract electrons from the electron source, where the aperture may substantially align with the CNT of the electron source when the extractor and electron source are mated to form the electron gun. The electron source and extractor may have alignment features for aligning the electron source and the extractor, thereby bringing the aperture and CNT into substantial alignment when assembled. The alignment features may provide and maintain this alignment during operation to improve the field emission characteristics and overall system stability of the electron gun.

Abstract: An electron gun, an electron source for an electron gun, an extractor for an electron gun, and a respective method for producing the electron gun, the electron source and the extractor are disclosed. Embodiments provide an electron source utilizing a carbon nanotube (CNT) bonded to a substrate for increased stability, reliability, and durability. An extractor with an aperture in a conductive material is used to extract electrons from the electron source, where the aperture may substantially align with the CNT of the electron source when the extractor and electron source are mated to form the electron gun. The electron source and extractor may have alignment features for aligning the electron source and the extractor, thereby bringing the aperture and CNT into substantial alignment when assembled. The alignment features may provide and maintain this alignment during operation to improve the field emission characteristics and overall system stability of the electron gun.