WO2022098258A1

WO2022098258A1 - Linear aberrational charged particle accelerator

Info

Publication number: WO2022098258A1
Application number: PCT/RU2021/000408
Authority: WO
Inventors: Владимир Сергеевич ЮНИН; Сергей Николаевич ЮНИН
Original assignee: Владимир Сергеевич ЮНИН; Сергей Николаевич ЮНИН
Priority date: 2020-11-03
Filing date: 2021-09-22
Publication date: 2022-05-12
Also published as: RU2020136058A; RU2020136058A3

Abstract

The invention relates to an accelerator for obtaining accelerated beams of charged particles and for implementing the concept of aberrational self-acceleration. The accelerator comprises a source of primary particles for acceleration, an acceleration path consisting of acceleration sections, a high-voltage power supply system, a vacuum system and other components typical of an acceleration apparatus. An elongate acceleration electrode at a high voltage is arranged in the middle of an acceleration section, and acceleration tubes connected to the acceleration electrode are arranged at the ends of the acceleration section. The end electrodes of the acceleration section are earthed. The earthed ends of the acceleration sections are designed to allow vacuum pumps to be used at the inlet and outlet of the acceleration sections. The layout of the acceleration path allows the energy of the particles to be increased either by increasing the voltage at the acceleration electrode and increasing the length thereof, or by adding additional acceleration sections. The technical result is the lack of any limits on the energy of the particles being accelerated and the acceleration of the particles to an energy that significantly exceeds the energy of the applied high voltage.

Description

LINEAR ABERRATION ACCELERATOR OF CHARGED PARTICLES

Description

The invention relates to accelerator technology and can be used to obtain accelerated beams of charged particles. The operation of all accelerators is based on the acceleration of charged particles by an electric field. Modern linear accelerators are divided into several types according to the method of accelerating charged particles: direct action accelerators, induction accelerators, linear resonant accelerators.

In direct action accelerators [1], the accelerated particle moves in the accelerating tube in a constant electric field, and the final energy of the accelerated particle in electron volts (eV) is numerically equal to the product of the electric voltage between the electrodes in volts and the particle charge. The main advantages of such accelerators are continuous operation, high efficiency, rather high currents of accelerated particles, the possibility of a smooth change in the energy of the beam of accelerated particles, and a small energy spread in the energy of particles. All direct action accelerators are high-voltage machines, which complicates their operation and limits the voltage used, not exceeding a few megavolts. The scheme of the accelerating path of such accelerators does not allow one to use them sequentially to increase the energy of particles. This imposes a limit on the energy of accelerated particles. Direct action accelerators operate in both continuous and pulsed modes.

In linear induction accelerators [1], the beam is accelerated by a longitudinal vortex electric field. The accelerator is a modification of the transformer, in which the secondary winding is a straight conductor. Sections of such a transformer are called inductors. The number of inductors installed in series one after another can be arbitrarily large and, accordingly, the energy of the particles increases in proportion to this number. A vacuum accelerating tube passes through the holes of the inductors along the entire length. The average electric field strength created by the inductor is equal to units of kV/cm. Therefore, when accelerating particles to high energies (on the order of tens of MeV), the disadvantage of such an accelerator is its considerable length. However, the advantage of such accelerators is the production of large pulsed electron currents. Such accelerators operate only in the pulse mode.

In linear resonant accelerators [2], acceleration is carried out by a high-frequency electric field. In order to achieve the required energy, the accelerated particles repeatedly pass through accelerating gaps - resonators, so there are no restrictions for reaching an energy of tens of GeV. The maximum energy is increased by adding additional accelerating sections. For efficient transfer of energy from the field to a particle, a certain correspondence must be maintained at each moment of time between the particle velocity and the velocity of the accelerating electromagnetic waves (frequency of the accelerating field). This requires powerful and complex RF electrical equipment. These accelerators operate only in pulsed mode.

The closest analogue of a linear aberration accelerator is a direct action accelerator in which a charged particle is accelerated by a constant electric field. It is traditionally believed that the charge is accelerated by an electric field between the electrodes, while there is no field inside the electrodes and the charge drifts without accelerating, i.e. It is assumed that a force independent of its velocity acts on a charge moving in an electric field. This contradicts the fact that the speed of electrical interaction is finite and equal to c, the speed of light. The final velocity of the electric field and the movement of the charge in it cause an aberration of the electric “signal” of this field, which leads to a change in the direction of the “signal” and, accordingly, a change in the direction of the force acting on the charge from the field [3], i.e. the electric force ceases to be central. The module of the force acting on the charge will be equal to the product of the charge and the module of the field strength, and the direction of the force will differ from the direction of the field strength, according to [4], by the angle of aberration. Therefore, the force of interaction of the charge with the field is not constant, but depends on the speed of the charge. This leads to the fact that the charge is accelerated not only between the electrodes, but also inside them [5]. Thus, the charge acquires energy not only passing through the potential difference between the electrodes, but also moving inside the electrodes, aberrationally self-accelerating. The charge energy depends not only on the applied voltage, but also on the geometry of the accelerating electrode, its shape and length.

To implement the idea of aberrational self-acceleration, an accelerator is proposed that includes a source of primary particles for acceleration, an accelerating path consisting of accelerating sections, a high-voltage power supply system, a vacuum system, and other components traditional for accelerator equipment. In the middle of the accelerating section there is an extended accelerating electrode under high voltage, at the ends there are accelerating tubes connected to the accelerating electrode. The end electrodes of the accelerating section are grounded. The aberrational self-acceleration of charged particles makes it possible to use the proposed scheme of the accelerating path for accelerating particles to energies significantly exceeding the energy of the applied high voltage. The grounded end electrodes of the accelerating sections make it possible to use vacuum pumps at the inlet and outlet of the accelerating sections, which significantly increases the efficiency of accelerating section evacuation. Such a scheme of the accelerating tract makes it possible to increase the energy either by increasing the voltage on the accelerating electrode and increasing its length, or by adding additional accelerating sections. An aberrational linear accelerator has all the positive properties of direct action accelerators and, like linear resonant accelerators, has no restrictions on the energy of accelerated particles.

The proposed design of the aberration accelerator with one accelerating section is illustrated in Fig. 1. Numbers in the figure indicate: 1 - accelerator body; 2 - accelerating electrode; 3 - accelerating tubes; 4 - power inputs, allowing for independent power supply of each accelerating section; 5 - vacuum pumps; 6 - magnetic elements for forming a beam of accelerated particles; 7 - grounded electrodes; 8 - source of charged particles. Literature:

1. Komar E.G. Fundamentals of accelerator technology - Moscow: Atomizdat, 1975. - 368 p.

2. Waldner O.E. Linear accelerators - Moscow: Atomizdat, 1969. - 248 p.

3. Yunin V. S. Model of the interaction of two point charges moving uniformly and rectilinearly// Physical education in universities - v.25 - No. 1 - 2019 - p. 86-95

4. Yunin V.S. Signal aberration model for uniform rectilinear motion of a point source or receiver relative to a homogeneous isotropic medium// Physical education in universities - v.23 - No. 4 - 2017 - p.65-70

5. Yunin V.S. Interaction of a point charge moving perpendicular to an infinite uniformly charged plane with the electric field of this plane// Physical education in universities - v.26 - No. 4 - 2020 - p.32-37.

Claims

Claims of the invention A linear aberration accelerator of charged particles containing a source of primary particles for acceleration, an accelerating path, a high-voltage power supply system, a vacuum system and other components traditional for accelerator equipment, characterized in that the accelerating path is divided into accelerating sections in which: end electrodes are grounded; in the middle there is an extended accelerating electrode under high voltage; at the ends there are accelerating tubes connected to the accelerating electrode. Linear aberration accelerator according to claim 1, characterized in that to change the energy of accelerated particles, the value of the high voltage on the accelerating electrode is changed. Linear aberration accelerator according to claim 1, characterized in that to change the energy of the accelerated particles, the geometry of the accelerating electrode, its length and shape are changed. Linear aberration accelerator according to claim 1, characterized in that the number of accelerating sections is changed to change the energy of accelerated particles. A linear aberration accelerator according to claim 1, characterized in that the source of primary particles for acceleration and the equipment for outputting the accelerated particle beam are grounded. Linear aberration accelerator according to claim 1, characterized in that grounded electrodes allow the use of vacuum pumps at the beginning and end of the accelerating section, which improves the degassing of the accelerating path.

SUBSTITUTE SHEET (RULE 26)