A system and method for generating X-ray radiation in a predefined spatial distribution on an anode. The system includes an anode, a first switching device, a second switching device, a control unit, and an emitter with multiple field effect emitter needles. At least one field effect emitter needle of the multiple field effect emitter needles includes a diameter of less than 1 m and silicon. A first group of the multiple field effect emitter needles may be activated or deactivated by the first switching device. A second group of the multiple field effect emitter needles may be activated or deactivated by the second switching device. The first group differs from the second group. The control unit is configured to actuate the first switching device and the second switching device.

A computer tomograph (1) for X-ray imaging includes a rotationally fixed gantry (2) that is displaceable at most in the axial direction (z). A plurality of X-ray emitters (3) and X-ray detectors (4) is arranged in the gantry (2) in a fixed manner about a central geometrical axis (z), in each case opposite to one another and offset with respect to each other in the direction of the central axis (z). The X-ray emitters (3) have cathodes (5) as electron emitters, which are separately connected to emitter controls (25) and cooperate with a common extraction grid (26) connected upstream of at least one focusing electrode (27). In comparison to conventional computer tomographs having rotating or rigidly arranged technical X-ray components, the computer tomograph (1) has a light and compact design.

A method, in an embodiment, is for setting an X-ray intensity using a structured anode or a field emitter cathode or a finger-shaped cathode head. Other embodiments include an associated X-ray device, an associated single X-ray tube CT scanner, an associated dual X-ray tube CT scanner, and an associated computer program product.

Presented systems and methods facilitate efficient and effective monitoring of particle beams. In some embodiments, a radiation gun system comprises: a particle beam gun that generates a particle beam, and a gun control component that controls the gun particle beam generation characteristics, including particle beam fidelity characteristics. The particle beam characteristics can be compatible with FLASH radiation therapy. Resolution control of the particle beam generation can enable dose delivery at an intra-pulse level and micro-bunch level. The micro-bunch can include individual bunches per each 3 GHz RF cycle within the 5 to 15 sec pulse-width. The FLASH radiation therapy dose delivery can have a bunch level resolution of approximately 4.410{circumflex over ()}6cGy/bunch.

A target for generating x-rays includes at least one substrate including a first material and a plurality of discrete structures including at least one second material configured to generate x-rays in response to electron bombardment. The discrete structures are distributed across a first surface of the at least one substrate in an array pattern function A that has a corresponding function B such that a combination operation of the array pattern function A with the corresponding function B generates a resultant function C comprising a first portion with a single peak and a substantially flat second portion surrounding the first portion. The combination operation includes a cross-correlation operation or a convolution operation

A tomosynthesis system has an x-ray source with an addressable array of electron emitting sections on the cathode. The x-ray source moves rotationally about an imaging target, such as a breast. During the rotation, x-rays are emitting from the x-ray source while the x-ray source continues to move. During the emission of x-rays, different subsets of electron-emitting sections of the addressable array are activated to compensate for movement of the x-ray source. By activating the different subsets of electron-emitting sections, an effective focal spot of the x-ray position appears to retain the same shape, size, and position from the perspective of the imaging target, despite movement of the x-ray source itself.

The object of the present invention is to provide a cold cathode X-ray tube capable of being driven stably over a long period of time by preventing temporal reduction in anode current. A cold cathode X-ray tube 1 comprises an electron emission part 10 including an electron emission element using a cold cathode, an anode part 11 disposed opposite to the electron emission part 10, a target 12 disposed on a part of a surface of the anode part 11, a housing 15 in which the electron emission part 10, the anode part 11, and the target 12 are disposed, and a hydrogen generation part 14 that is made of a material that generates hydrogen when receiving collision of electrons and disposed on a portion other than the surface of the target 12 out of surfaces existing in the housing 15.

A field emission electron source and a method of manufacturing the same. A field emission electron source comprises an emitting electrode and an extractor gate electrode. The emitting electrode comprising a plurality of particles with nanosharp protrusions. The extractor gate electrode comprises a metal. The extractor gate electrode is formed in a same plane as the emitting electrode. The extractor gate electrode is formed surrounding the emitting electrode. A method of manufacturing a field emission electron source comprises forming an emitting electrode comprising a plurality of particles with nanosharp protrusions using a direct ink writing (DIW) printer. The method comprises forming an extractor gate electrode comprising a metal using the DIW printer.

A cylindrical X-ray tube having an outer insulating layer, a cathode electrode and an anode electrode disposed at both ends of the outer insulating layer, a gate electrode disposed between the cathode and anode electrodes, an emitter, and a target, comprises an inner insulating layer which is disposed between the cathode electrode and the outer insulating layer, is formed to extend downward in a coaxial direction with the outer insulating layer, and is pre-adjusted in order to secure an insulating distance between the cathode electrode and the gate electrode. Thus, by providing a separate internal insulating layer extending coaxially with the external insulating layer between the cathode electrode and the external insulating layer, the insulating distance between the cathode electrode and the gate electrode, the insulating distance between the cathode electrode and the anode electrode may be easily adjusted, so that a desired insulating capability can be secured.

An x-ray tube includes an electron emitter and a cathode cup having a recess that holds the electron emitter. The recess has a bottom surface, and a shield is positioned in the recess between the electron emitter and the bottom surface. The shield is configured to receive deposited sublimated emitter material and to maintain the sublimated emitter material away from the electron emitter.