Radio frequency superconducting cavity with slit waveguide structure for superconducting accelerator

Abstract

The invention relates to a radio frequency superconducting cavity with a slot waveguide structure for a superconducting accelerator, which belongs to the technical field of accelerator physics. The radio frequency superconducting cavity comprises multiple oval spherical cavities, bundle tubes and alary slit waveguides, wherein the multiple oval spherical cavities are connected with one another in series; both ends of the multiple oval spherical cavities which are connected with one another are the bundle tubes; each oval spherical cavity and the outer walls of the bundle tubes at the two ends are uniformly distributed with multiple slits along the circumferential direction; and the slits of each oval spherical cavity and the slits of the bundle tubes at the two ends are connected by the corresponding alary slit waveguides. The radio frequency superconducting cavity of the invention has super-high attenuation of a dipole module and a quadrupole module, so that ERL of GeV magnitude reaches the average current intensity of ampere magnitude; the radio frequency superconducting cavity can reach a BBU threshold value over the ampere magnitude; the radio frequency superconducting cavity can be formed by punching at one time due to no weld joint in a high electric field; therefore, machining difficulty is greatly reduced, time and cost for product production are reduced, the products are suitable for mass production, and the production cost is reduced.

Description

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AI Technical Summary

Benefits of technology

This new type of device called an ion imager (IMS) uses special materials like quantum dots or semiconductor crystals instead of traditional electrodes used in conventional devices such as inductors. These special material have very strong electric fields which help them perform better than regular metal structures. By adding these special materials into this device's IMS chamber, its performance improves compared to previous designs without any modifications made by other methods.

Problems solved by technology

This patented technical problem addressed in this patents relates to improving the efficiency of electronics devices used during extreme ultraviolet radiation ("EEU") research or development. Current methods are limited because they require bulky structures like crystals which limit their ability to achieve strong magnetic fields.

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