JP2003124000A - Electron beam cooling device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problems of both the correction of track disturbance of circulating ion beam in an accelerator and the improvement in cooling of an electron beam cooling device. SOLUTION: Helmholtz-shaped deflecting electromagnets 9a and 9b for horizontal correction are arranged along one direction on the outside surface or inside surface of a cylindrical solenoid electromagnet 8 for correcting the rotation of the circulating ion beam 2 around a beam track axis, Helmholtz-shaped deflecting electromagnets 10a and 10b for vertical correction are provided along the other direction of the cylindrical solenoid electromagnet, and correcting electromagnets 7a and 7b integrally provided with them are arranged on the beam track of the circulating ion beam.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electron beam cooling device which is a component of an accelerator, and more particularly to a correcting electromagnet for correcting a beam orbit of an orbiting ion beam.

[0002]

2. Description of the Related Art Conventionally, in a circular accelerator such as an ion synchrotron or an ion storage ring, an electron beam cooling device is provided on the orbit of the orbiting ion beam for the purpose of expanding the momentum of the orbiting ion beam and reducing the emittance. There is. If such an electron beam cooling device is provided, the orbit of the orbiting ion beam may be disturbed by the influence of the magnetic fields of the central part electromagnet and the toroid part electromagnet of the electron beam cooling device. Therefore, the electron beam cooling device is provided with a correction electromagnet for the purpose of correcting the disturbance of the orbit of the orbiting ion beam.

The structure and arrangement of a conventional general electron beam cooling device and a correction electromagnet will be described below with reference to FIG.
The electron beam cooling device 1 is provided with a central part electromagnet 3 and toroid part electromagnets 4a and 4b on both sides of the central part electromagnet 3 on the beam orbit of the orbiting ion beam 2 traveling along the arrow A direction. The orbiting ion beam 2 traveling along the arrow A direction on the beam orbit of the ion synchrotron or the ion storage ring passes through the toroid part electromagnets 4 a and 4 b and the central part electromagnet 3 of the electron beam cooling device 1 . The orbiting ion beam 2 has a toroidal electromagnet 4a,
When passing through the inside of 4b, arrow B is generated due to the influence of the magnetic field.
The beam passes through a position deviated from the center of the beam trajectory because it receives a force in the vertical direction with respect to the paper surface. When the orbiting ion beam 2 passes through the inside of the central electromagnet 3, the orbiting ion beam 2 rotates around the beam orbit axis due to the influence of the magnetic field. In order to correct the disturbance of the orbit of the orbiting ion beam 2, the electron beam cooling device 1 is provided with a correction steering electromagnet 5 and a correction solenoid electromagnet 6.

When the orbiting ion beam 2 that has passed through the electron beam cooling device 1 passes through the inside of the correction steering electromagnet 5, the magnetic field corrects the deviation of the orbit that occurs when it passes through the toroid part electromagnets 4a and 4b. When the orbiting ion beam 2 that has passed through the electron beam cooling device 1 passes through the inside of the correction solenoid electromagnet 6, the magnetic field corrects the rotation around the beam orbital axis that occurs when it passes through the central portion electromagnet 3.

In order to enhance the effect, the correction steering electromagnet 5 and the correction solenoid electromagnet 6 are generally provided in pairs before and after the electron beam cooling device 1 . Examples of this type of device include "T. Tanabe et al .: Electron coolin
g experiments at INS, Nuclear Instruments and Met
Hod in Physics Research A307 (1991) 7-25 ”describes the configuration, arrangement, and operation of the electron beam cooling device, the correction steering electromagnet, and the like.

[0006]

In the electron beam cooling device 1 as described above, the axial length along the beam orbit of the central electromagnet 3 is lengthened or the magnetic field strength of the central electromagnet 3 is increased. This is advantageous in improving the cooling performance. However, if the axial length along the beam trajectory of the central part electromagnet 3 is increased or the magnetic field strength is increased to improve the cooling performance, it occurs when the orbiting ion beam 2 passes through the inside of the central part electromagnet 3. The amount of rotation around the beam orbit axis also increases.
Therefore, in order to correct the rotation of the orbiting ion beam, it becomes necessary to increase the length of the correction solenoid electromagnet 6 or increase the magnetic field strength. However, in an actual ion synchrotron or ion storage ring, there are restrictions in order to avoid interference with devices such as the above-mentioned correction steering electromagnet 5 and other quadrupole electromagnets, and the dimensions are increased or the magnetic field strength is increased. There is a limit to raising. Therefore, it has been difficult to achieve both the improvement of the cooling performance of the electron beam cooling device 1 and the correction of the orbital disturbance of the orbiting ion beam 2.

The present invention has been made to solve the above problems, and is an electron beam cooling device which is small in a limited space, has improved cooling performance, and can surely correct the orbit of an orbiting ion beam. The purpose is to provide.

[0008]

According to a first aspect of the present invention, there is provided a correction electromagnet arranged on the beam orbit of a circular ion beam, the correction electromagnet including a cylindrical solenoid electromagnet and And a Helmholtz-shaped deflection electromagnet provided outside the solenoid electromagnet.

According to the present invention, the correction cylindrical solenoid electromagnet and the Helmholtz-shaped deflection electromagnet are integrated, and the correction electromagnet is miniaturized. The axial length of the central part electromagnet of the electron beam cooling device can be increased by that amount, and the cooling performance is improved by increasing the magnetic field strength of the central part electromagnet.

The invention according to claim 2 of the present invention comprises a correction electromagnet arranged on the beam orbit of the circular ion beam, and the correction electromagnet is a cylindrical solenoid electromagnet,
It is characterized by comprising a Helmholtz-shaped deflection electromagnet provided inside the solenoid electromagnet.

Also according to the present invention, the correction cylindrical solenoid electromagnet and the Helmholtz-shaped deflection electromagnet are integrated, and the correction electromagnet is miniaturized. The axial length of the central part electromagnet of the electron beam cooling device can be increased by that amount, and the cooling performance is improved by increasing the magnetic field strength of the central part electromagnet.

According to a third aspect of the present invention, in the electron beam cooling apparatus according to the first or second aspect, a Helmholtz-shaped deflection electromagnet is provided horizontally on a surface along one direction of a cylindrical solenoid electromagnet. A Helmholtz-shaped deflection electromagnet for direction correction and a Helmholtz-shaped deflection electromagnet for vertical direction correction provided on a surface along the other direction of the cylindrical solenoid electromagnet.

According to a fourth aspect of the present invention, in the electron beam cooling apparatus according to the first or second aspect, a Helmholtz-shaped deflection electromagnet for horizontal correction and a Helmholtz-shaped deflection electromagnet for vertical correction are provided. Are provided in pairs at positions facing each other.

Also in these inventions, the cylindrical solenoid electromagnet and the correction Helmholtz-shaped deflection electromagnet are integrated, and the correction electromagnet is miniaturized. The axial length of the central part electromagnet of the electron beam cooling device can be increased by that amount, and the cooling performance is improved by increasing the magnetic field strength of the central part electromagnet.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION A first embodiment of an electron beam cooling device of the present invention will be described below with reference to FIG. In FIG. 1, the electron beam cooling device 1 is provided with a central part electromagnet 3 and toroid part electromagnets 4a and 4b on both sides of the central part electromagnet 3 on the beam orbit of an orbiting ion beam 2 traveling along the arrow A direction. The orbiting ion beam 2 traveling along the direction of the arrow A on the beam orbit of the ion synchrotron or the ion storage ring is the electron beam cooling device 1.
Toroid part electromagnets 4a, 4b and central part electromagnet 3
Pass through each inside.

Reference numerals 7a and 7b are electromagnets provided on both sides of the electron beam cooling device 1 for correcting the beam trajectory of the circular ion beam. As shown in FIG. 2, the correction electromagnets 7a and 7b include a cylindrical solenoid electromagnet 8 that corrects rotation around the beam orbit axis, and a pair of integrally provided outer surfaces facing each other along one direction. Helmholtz-shaped deflection electromagnets 9a and 9b for horizontal correction, and a pair of vertical-correction Helmholtz-shaped deflection electromagnets 10a integrally provided on opposing outer surfaces along a direction orthogonal to the one direction. , 10b, and the integral correction electromagnets 7a, 7b are arranged on the orbit of the orbiting ion beam 2. When the orbiting ion beam 2 traveling on the orbit along the arrow A passes through the insides of the correction electromagnets 7a and 7b, the beam orbit axis of the orbiting ion beam 2 caused by the central electromagnet 3 of the electron beam cooling device 1 described above. The rotation around is corrected and corrected by the solenoid magnetic field of the cylindrical solenoid electromagnet 8. Similarly, when the orbiting ion beam 2 passes through the inside of the integral correction electromagnets 7a and 7b, the beam orbit center of the orbiting ion beam 2 caused by the toroid part electromagnets 4a and 4b of the electron beam cooling device 1 described above. The deviation in the direction of the arrow X with respect to is corrected and corrected by the magnetic field in the direction Y of the arrow of the horizontal correction Helmholtz-shaped deflection electromagnets 9a and 9b. At the same time, the deviation of the orbiting ion beam 2 in the arrow Y direction from the center of the beam orbit is corrected and corrected by the magnetic field in the arrow X direction of the vertical correction Helmholtz-shaped deflection electromagnets 10a and 10b.

As described above, according to the correction electromagnet of the present invention, the cylindrical solenoid electromagnet 8, the horizontal correction Helmholtz-shaped deflection electromagnets 9a and 9b, and the vertical correction Helmholtz-shaped deflection electromagnets 10a and 10b are used.
By integrating the two, the correction steering electromagnet and the correction solenoid electromagnet can be arranged separately and installed on the orbit of the orbiting ion beam, which reduces the installation space and makes the electron beam cooling device. It is possible to shorten the length in the beam axis direction of the region required to correct the resulting disturbance of the orbiting ion beam, and it is possible to downsize the electron beam cooling device itself while improving the cooling effect.

FIG. 3 shows a modification of the first embodiment of the present invention, which is a Helmholtz-shaped bending electromagnet 9 for horizontal correction.
a and 9b and Helmholtz-shaped deflection electromagnets 10a and 10b for vertical correction are integrally attached to the inner surface of the cylindrical solenoid electromagnet 8. Even in this case, the same operation and effect as those of the first embodiment of the present invention shown in FIG. 1 can be obtained.

Further, in the embodiment shown in FIGS. 1 and 2, the deflection electromagnet 9 of the Helmholtz shape for horizontal correction is used.
It is possible to omit either one of a and 9b and the Helmholtz-shaped deflection electromagnets 10a and 10b for vertical direction correction. In that case, the action of the pair of Helmholtz-shaped deflection electromagnets omitted is subtracted from the action of the embodiment shown in FIGS. 1 and 2, but some action and effect can be expected.

The correction electromagnets 7a and 7b according to the present invention are also provided.
It is also possible to integrate the above into the inside of the conventional electron beam cooling device. By such integration, the device is further downsized as compared with the case where the electron beam cooling device and the correction electromagnet are individually installed, so that the cooling performance is improved while ensuring the correction of the disturbance of the orbiting ion beam. The effect of the present invention is further increased.

Furthermore, an electron beam cooling device in which an integral correction electromagnet is incorporated in the ion synchrotron or the ion storage ring may be provided. By doing so, it is possible to shorten the ion beam accumulation time, which can be utilized for efficient scientific / engineering experiments or industrial applications. Moreover, it becomes possible to accumulate short-lived atomic nuclei, which can be useful for nuclear research and radiotherapy using unstable atomic nuclei, which has been impossible in the past.

[0022]

As described above in detail, according to the present invention, a cylindrical solenoid electromagnet and a Helmholtz-shaped deflection electromagnet provided outside the solenoid electromagnet are arranged and arranged on the beam orbit of a circular ion beam. Since the correction electromagnet is provided, it is possible to obtain an electron beam cooling device which is small in a limited space, has improved cooling performance, and can surely correct the orbit of an orbiting ion beam.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a first embodiment of the present invention.

FIG. 2 is an enlarged view showing a correction electromagnet according to the first embodiment of the present invention, in which (a) is a schematic side view and (b) is a view taken along line IIb-IIb of FIG. Sectional view seen in.

FIG. 3 is a diagram showing a modified example of the first embodiment of the present invention, in which (a) is a schematic side view and (b) is a diagram (a) in IIIb-I.
Sectional drawing cut | disconnected along IIb and seen in the arrow direction.

FIG. 4 is a schematic configuration diagram showing the configuration and arrangement of a conventional general electron beam cooling device and a correction electromagnet.

[Explanation of symbols]

1 ... Electron beam cooling device, 2 ... Orbiting ion beam, 3 ...
Central part electromagnet, 4a, 4b ... Toroid part electromagnet,
7a, 7b ... Correction electromagnets, 8 ... Cylindrical solenoid electromagnets, 9a, 9b ... Helmholtz-shaped deflection electromagnets for horizontal correction, 10a, 10b ... Helmholtz-shaped deflection electromagnets for vertical correction.

Claims (4)

[Claims] 1. A correction electromagnet arranged on the beam trajectory of a circular ion beam, the correction electromagnet comprising a cylindrical solenoid electromagnet and a Helmholtz-shaped deflection electromagnet provided outside the solenoid electromagnet. An electron beam cooling device characterized by the above. 2. A correction electromagnet arranged on the beam orbit of a circular ion beam, the correction electromagnet comprising a cylindrical solenoid electromagnet and a Helmholtz-shaped deflection electromagnet provided inside the solenoid electromagnet. An electron beam cooling device characterized by the above. 3. A Helmholtz-shaped deflection electromagnet is provided on a surface along one direction of a cylindrical solenoid electromagnet, and a Helmholtz-shaped deflection electromagnet for horizontal correction is provided on a surface along another direction of the cylindrical solenoid electromagnet. 3. The electron beam cooling device according to claim 1, wherein the electron beam cooling device is a Helmholtz-shaped bending electromagnet provided for vertical correction. 4. The electron beam cooling device according to claim 1, wherein a pair of a Helmholtz-shaped deflection electromagnet for horizontal direction correction and a Helmholtz-shaped deflection electromagnet for vertical direction correction are provided in a pair so as to face each other.