A quality assurance device for a medical accelerator includes a housing having an inner radioluminescent layer adapted to provide a visual indication when contacted with invisible radiation generated by the medical accelerator. In addition, the quality assurance device includes one or more passive optical components within the housing adapted to deliver an image of the inner radioluminescent layer of the housing including the visual indication to one or more cameras located outside of the housing.

A quality assurance device for a medical accelerator includes a housing having an inner radioluminescent layer adapted to provide a visual indication when contacted with invisible radiation generated by the medical accelerator. In addition, the quality assurance device includes one or more passive optical components within the housing adapted to deliver an image of the inner radioluminescent layer of the housing including the visual indication to one or more cameras located outside of the housing.

Embodiments of systems, devices, and methods relate to an ion beam source system. An ion source is configured to provide a negative ion beam to a tandem accelerator system downstream of the ion source, and a modulator system connected to an extraction electrode of the ion source is configured to bias the extraction electrode for a duration sufficient to maintain acceleration voltage stability of the tandem accelerator system.

The present disclosure provides a microwave transmission method and a single-input multiple-output waveguide microwave system based on frequency control, an electronic device. The method includes: adjusting frequency of an input microwave, each of different input microwaves with different frequencies being input microwave of the single-input multi-output waveguide microwave system; assigning the input microwave to a target output port among multiple output ports of the single-input multiple-output waveguide microwave system, according to the frequency of the input microwave; and performing microwave output through the target output port.

In one exemplary aspect, the subject matter described in this specification can be embodied in an energy extraction system that includes a decelerator cavity coupled to a transport line for a charged particle beam and an energy conversion device coupled to the decelerator cavity. The decelerator cavity is configured to extract energy from the charged particle beam traveling through the decelerator cavity as RF energy. The energy conversion is configured to convert the RF energy into electrical current and supply the electrical current to an electric power grid. The charged particle beam includes charged particles with individual rest masses greater than the rest mass of an electron.

A radio frequency electron accelerator structure for local frequency modulation includes an accelerating cavity, a coupling cavity, and a beam hole. The accelerating cavity and the coupling cavity are alternately assembled together, and the beam hole penetrates the accelerating cavity and the coupling cavity. A local cutting area is arranged inside both the accelerating cavity and the coupling cavity. A local frequency modulation method for a radio frequency electron accelerator is further provided. In the frequency modulation stage of the accelerating cavity, the local cutting area of the accelerating cavity is cut. When the feed amount is large, the change of the volume of the cavity is still small, and the generated frequency variation of the cavity is small, which significantly reduces the difficulty of frequency modulation, lowers the accuracy requirements of machine tools at the same time, and decreases the cost of enterprises accordingly.

A radio frequency electron accelerator structure for local frequency modulation includes an accelerating cavity, a coupling cavity, and a beam hole. The accelerating cavity and the coupling cavity are alternately assembled together, and the beam hole penetrates the accelerating cavity and the coupling cavity. A local cutting area is arranged inside both the accelerating cavity and the coupling cavity. A local frequency modulation method for a radio frequency electron accelerator is further provided. In the frequency modulation stage of the accelerating cavity, the local cutting area of the accelerating cavity is cut. When the feed amount is large, the change of the volume of the cavity is still small, and the generated frequency variation of the cavity is small, which significantly reduces the difficulty of frequency modulation, lowers the accuracy requirements of machine tools at the same time, and decreases the cost of enterprises accordingly.

A compact particle accelerator can include two or more cavities disposed along an axis of the particle accelerator, each of which is coupled to two or more drivers. The accelerator can also include a power supply coupled to the two or more drivers such that a particle beam traveling along the axis is accelerated. The power supply can be an interface with a commercial power outlet, battery power, or a combination thereof depending upon the use case. Example configurations of the accelerator include hand held or mobile devices that are capable of delivering up to and greater than a 1 MeV electron beam.

A compact particle accelerator can include two or more cavities disposed along an axis of the particle accelerator, each of which is coupled to two or more drivers. The accelerator can also include a power supply coupled to the two or more drivers such that a particle beam traveling along the axis is accelerated. The power supply can be an interface with a commercial power outlet, battery power, or a combination thereof depending upon the use case. Example configurations of the accelerator include hand held or mobile devices that are capable of delivering up to and greater than a 1 MeV electron beam.

An isochronous cyclotron including one or more coils and a plurality of pairs of bulk superconductor sectors. The one or more coils can be configured to generate a magnetic field in the beam chamber having a magnetic flux density that increases radially from the central axis of the beam chamber, and is orientated substantially perpendicular to the median acceleration plane of the beam chamber. Each pair of bulk superconductor sectors can be disposed on opposite sides of the median acceleration plane. The plurality of pairs of bulk superconductor sectors can be configured to guide or concentrate the magnetic field to provide an axial focusing component of the magnetic field.