RU2605949C1 - Accelerating structure with parallel connection - Google Patents

Abstract

FIELD: electronics.

SUBSTANCE: invention relates to acceleration equipment, is intended for electrons acceleration by SHF field at simultaneous retention of beam next to specified axis by solenoidal type magnetic field. Device contains accelerating structure with parallel connection, which accelerating resonators are structurally separated by gaps, in gaps radially magnetized annular permanent magnets are installed, creating sign-variable magnetic field on resonators axis. Divisible magnets allow for acceleration structure heating.

EFFECT: technical result is possibility of electrons acceleration by SHF field with high current (not less than 1A) electron beam simultaneous retention by permanent magnets magnetic field on accelerating resonators axis with magnets relatively low total weight, due to system design selection in general, embedding focusing magnets inside accelerating structure and using reverse focusing.

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Description

The invention relates to physics of charged particle beams and accelerator technology, is intended to accelerate charged particles by a microwave field while holding the beam near a given axis with a magnetic field of the solenoidal type.

Known electron accelerator containing an accelerating structure for accelerating electrons, and mounted on top of the structure of the focusing solenoid, the axis of which coincides with the axis of the accelerating resonators of the structure, creating a uniform magnetic field for focusing the beam [1].

However, since the magnetic field is created not only in the region of particle motion - near the axis of the accelerating resonators, but also in the entire volume of the system, the weight of the focusing solenoid and its power supply and cooling devices is significant, and a large power consumption is required.

A focusing reversible magnetic system is known, containing coaxially mounted ring magnets with alternating radial magnetization, creating an alternating magnetic field of the solenoidal type magnetic field for focusing electrons in microwave power generation devices, for example, in klystrons [2], TWT [3]. An alternating magnetic field is created by permanent magnets, and due to the radial magnetization of the magnets practically only in the region of particle motion — near the beam axis, the weight of the magnetic system is therefore relatively small. However, in accelerator technology, an alternating magnetic field is not used to focus the beam, because due to the large diameter of the accelerating resonators included in the structure, determined by the working wavelength, and, accordingly, the large diameter of the accelerating structure, it is almost impossible to create sufficient magnets with permanent magnets mounted on top of the structure magnetic field on the axis of the accelerating resonators of the structure.

Known is an accelerating structure of a new type, containing coaxially mounted accelerating resonators and a common resonator for them, to accelerate electrons [4], in which microwave power is supplied to the accelerating resonators through their side walls.

The objective of the invention is to develop a new device for the simultaneous acceleration of electrons by the microwave field and focusing the beam by the field of permanent magnets.

The problem is solved by the claimed device containing an accelerating structure with parallel coupling and permanent magnets, which allows, due to the choice of the system design, to simultaneously accelerate the particles with a high-frequency electric field in the resonators of the accelerating structure and focus the beam with an alternating magnetic field of the solenoidal type.

To achieve this goal, an accelerating structure with parallel coupling was used, in which microwave power is supplied to the accelerating resonators through their side walls [4]. In FIG. Figure 1 shows the diagram of the proposed device (bottom right), the section of the device (left), and the calculated dependence, in relative units, of the accelerating electric field Eass and the focusing magnetic Bfoc field with reference to the longitudinal coordinate. The geometry of the accelerating structure with parallel coupling allows the installation of accelerating resonators with gaps between them and the placement of permanent magnets in the indicated gaps.

Accelerating resonators 1 of the accelerating structure (Fig. 1) have communication holes 2 for inputting microwave power from a common pass-through exciting resonator 3. The input of microwave power (RF) into the exciting resonator from the input waveguide is through the input communication diaphragm 4. The protrusions 5 serve for tuning the exciting resonator to the operating wavelength.

Accelerating resonators are separated by gaps (section AA is made along one of the intervals), in which permanent magnets 6 are embedded (on section AA, arrows indicate the direction of the magnetic field).

The calculated values of the accelerating electric Eass and focusing magnetic Bfoc fields corresponding to the selected geometry with reference to the longitudinal coordinate are shown in the graph above the diagram of the accelerating structure.

To substantiate the essence of the invention, we consider the nature of the movement of accelerated particles in an accelerating structure, the scheme of which is shown in FIG. 2. Acceleration of particles occurs in the electric fields shown by the arrows of the Eass resonators 1, focusing is carried out by the magnetic field of the magnets 2. The longitudinal value of the magnetic field, in relative units, is shown by the Bfoc curve (the direction of the magnetic field in the magnets is shown by the arrow). Magnets are placed in the spaces between the resonators. The inner diameter of the magnet rings is less than the diameter of the resonators. Microwave power is introduced into accelerating resonators through communication holes from a common exciting resonator, as shown in FIG. one.

Let the particles move from left to right near the axis of symmetry of the accelerating resonators O. In region A of a zero value of the magnetic field, the accelerating field is also zero, electromagnetic particles do not act on the particles, and they move by inertia. Further, when entering a magnetic field, due to the transverse component of the magnetic field and the longitudinal velocity, the particles receive momentum in a plane perpendicular to the axis of symmetry of the magnetic field. Due to this pulse and the longitudinal component of the magnetic field, a focusing force arises proportional to the square of the magnetic field [5]. This force is directed to the axis of symmetry of the confining magnetic field; therefore, when entering the magnetic field, the beam is centered as a whole relative to the axis of symmetry of the indicated field. Further, when entering the resonator 1, the particles fall into the region of a nonzero accelerating electric field and are accelerated. When leaving the resonator, the particles fall into the region of a decreasing magnetic field and, accordingly, reduce their momentum in the plane perpendicular to the axis of symmetry of the magnetic field in region B to zero. In region B, the zero value of the magnetic field, the process is repeated, with the difference that the longitudinal and transverse directions of the indicated field are reversed. Accordingly, it changes to the opposite direction of the particle lateral velocity vector. However, since the focusing force is proportional to the vector product of the transverse component of the particle velocity and the longitudinal component of the magnetic field, and both of these vectors have changed direction, the focusing force vector does not change sign and is directed to the axis of symmetry of the magnetic field of the system [5]. Then, upon entering the next accelerating cavity, the particles again fall into the region of a nonzero accelerating field and are accelerated. The phase relations of the accelerating fields in the adjacent resonators of the accelerating structure with parallel coupling are determined by the exciting resonator [4].

Thus, in the inventive device, there is both sequential acceleration of charged particles along the axis of accelerating resonators, and focusing on this axis of both individual particles and the beam as a whole. Since in the accelerating structure with parallel coupling, adjacent accelerating resonators are not directly connected to each other and have only a common channel for beam passage, and microwave power is input through the communication holes, it is possible to arrange structural gaps between them. When installed in the gaps of permanent magnets, the inner diameter of the ring magnets is determined not by the diameter of the resonator, but by the diameter of the passage channel, which is significantly smaller than the diameter of the resonator, and when the magnets are radially magnetized, an alternating longitudinal magnetic field is created almost only near the beam axis. Due to such a reverse input of a magnetic field to the beam axis, the weight of the magnetic system decreases by about N ² times, where N is the number of magnetic field reversals along the length of the accelerating system compared to a uniform magnetic field [5].

An experimental verification of the proposed device was carried out. Using numerical simulation, we found the sizes, locations of accelerating resonators and the magnitude of the fields in them, the magnitude of the focusing magnetic fields of the system. The calculated values of accelerating electric Eass and focusing magnetic Bfoc fields with reference to the longitudinal coordinate are shown in FIG. 1. In accordance with the calculation, a prototype of an accelerating structure with parallel coupling was made, containing five accelerating resonators and permanent magnets for reversing focusing of the electron beam, and measurements were made with the electron beam. At an injection voltage of 50 kV, a beam of accelerated electrons with an energy of about 3 MeV, a high capture coefficient in the acceleration mode, and a small beam diameter at the output of the system was obtained. The photo (Fig. 3) on a thermographic film shows the trace of the beam at the output of the accelerator. The beam diameter does not exceed 3 mm. Without a magnetic field, the beam at the exit is not focused and its diameter exceeds the diameter of the accelerator outlet.

The technical result of the invention is the ability to accelerate an electron beam by a high-frequency field while simultaneously holding it near a given axis by a magnetic field of permanent magnets with a relatively small weight of magnets, by choosing the design of the system as a whole, placing focusing permanent magnets between accelerating resonators of the accelerating structure with parallel coupling and using a reversible focusing. The magnets can be collapsible, which allows the heating of the accelerating structure.

Literature

1. M. Reiser. Theory and Design of Charged Particle Beams. Iohn Wiley & Sons. 1994.P. 98.

2. I.A. Frejdovich, et al. MULTY-BEAM KLYSTRONS WITH REVERSE PERMANENT MAGNET FOCUSING SYSTEM AS THE UNIVERSAL RF POWER SOURCES FOR THE COMPACT ELECTRON ACCELERATORS. Proc. of RuPAC 2006.P. 100.

3. Mendel J.T. Electron beam focusing. Pat. US 2,855,537 A, 1953.

4. Chernousov Yu.D., Ivannikov V.I., Shebolaev I.V., Levichev A.E., Pavlov V.M. Accelerating structure with parallel communication. Pat. RU 2472244 C1. Publ. 01/10/2013. Bull. No. 1.

5. S.I. Molokovsky, A.D. Sushkov. Intense electron and ion beams. M .: Energoatomizdat. 1991.S. 196-217.

Claims (2)

1. An accelerating structure with parallel coupling, including coaxially mounted accelerating resonators, characterized in that the said resonators are spaced, permanent ring magnets with alternating radial magnetization are placed in such a way that the axis of symmetry of the magnets and the generated magnetic field coincides with the axis of the accelerating resonators , the inner diameter of the magnet rings is less than the diameter of the accelerating resonators. 2. The accelerating structure according to claim 1, characterized in that the magnets are made collapsible.

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