RU2488243C2 - Plasma generator of deceleration radiation - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: plasma generator of deceleration radiation has a microwave resonator placed in a magnetostatic field with a plug configuration with a small plug ratio and excited by a microwave generator. Pulse-forming magnetic coils are placed on the microwave resonator in the interpole space of an electromagnet; the resonator is connected to a pulse gas valve which enables to form a powerful gas jet directed into the region of generating a bunch of accelerated electrons. A solid-state target is placed in the resonator outside the heating zone.

EFFECT: high radiation intensity, clear radiation pattern, which widens the spectral range of radiation in the region of hard X-rays.

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Description

The invention relates to the field of plasma physics and technology, and more particularly to plasma X-ray bremsstrahlung generators.

Currently, various methods for generating intense radiation fluxes in the x-ray range are known. However, in most of them (accelerator systems, plasma Z-pinches, etc.), the energy price of X-ray quanta is extremely high. As a result of this, essentially well-known x-ray tubes occupy a monopoly position in the market. Meanwhile, X-ray tubes have a number of disadvantages, among which the most serious are a sharp decrease in the stability of the work and the durability of the product with an increase in the accelerating voltage of over 100 kV, which is necessary to obtain hard radiation.

Typical characteristics of traditional sources of radiation of this type are presented in the table:

The characteristic features of most sources based on X-ray tubes are the presence of high voltage, the use of materials with high electric strength, significant size and low specific energy density, limited service life, low repetition rate of X-ray pulses, poor repeatability of spectra, safety problems, and high cost. Sources based on radioactive materials are also not universal and, first of all, their shortcomings boil down to difficulties encountered in working with them, storage, radiological safety and subsequent disposal of radioactive materials.

For non-destructive testing methods, a number of technologies, biogenetic studies and medical purposes, there is a need for small-sized radiation sources with a spectral energy range of 1-1000 keV. At the same time, energy consumption should be moderate, and the source should be electrically safe.

A device [1] is known in which plasma is used to generate X-ray radiation, which is held in a simple mirror magnetic trap with an annular layer of hot electrons (ELMO project) [2]. A short current pulse with a duration of the order of 10 ns in an additional magnetic coil, which is located in the zone of confinement of the electron-hot plasma bunch, corrects the bunch path and shifts it relative to the axis of the magnetic trap. This leads to the landing of a bunch on a target located outside the region of its primary generation. The power of the generated radiation is determined by the characteristic transverse size of the bunch, the time of its cyclotron revolution and the energy distribution function of the bunch electrons. The main disadvantage of such a device is the difficulty of generating a short pulse current in magnetic coils with significant inductance. In addition, a correction coil is located in the region of bunch generation, which impedes the efficient process of resonant plasma heating and generation of a ring of hot electrons.

Known devices for generating x-rays based on a high-current discharge in a plasma diode [3-7] or using beams of energetic electrons [8]. The main disadvantages of such devices are: the need to use powerful pulsed voltage generators (with an output voltage amplitude of the order of ~ 10 ⁶ V), the use of high-current switching electronics elements, significant dimensions and weight. These factors limit the scope of their use, as they impose a number of requirements on the qualifications of service personnel, safety precautions, and transportation. In addition, devices of these types have a limited operational resource.

Closest to the technical nature of the claimed device are a microwave plasma source of x-ray radiation [9] and its analogues [10-16].

All these devices contain a microwave resonator placed in a magnetic field of the plug configuration in which the generated plasma is heated under conditions of classical electron cyclotron resonance (ECR) or its variations, such as, for example, heating at the second resonance harmonic. In the process of resonant interaction in the working volume of the resonator creates a nonequilibrium plasma with a population of "hot" electrons. Hot electrons of such a plasma are spatially concentrated near the ECR surface and serve as a potential source of bremsstrahlung with a wide spectral range. The width of the spectral region of the radiation and its intensity are determined by the power and frequency of the microwave generator, the spatial distribution of the magnetic field strength in the trap, the pressure value and other characteristics of the plasma-forming gas. To generate X-ray radiation, either a solid-state target placed in the ECR interaction region where the hot electron layer is concentrated [13–16] is used, or the radiation is generated by the interaction of hot electrons with the generated plasma ions and the cavity walls.

The main disadvantages of devices of this type are: the absence of pronounced anisotropy of the motion of hot electrons within the region of their interaction with the target, the absence of a pronounced directivity of the generated radiation, low radiation intensity due to the low density of hot electrons interacting with the target, the narrow spectral range of the generated radiation and its low intensity in high-energy region, determined by the energy distribution of a population of hot electrons, a small integral power st radiation because the radiation activated to generate a small part of the electrons focused on an ECR surface.

The technical result to which the invention is directed is to create a device that provides increased radiation intensity, the presence of a clear radiation pattern, the possibility of a controlled shift of the radiation spectrum towards hard X-ray radiation, while maintaining all the advantages of such systems: compactness, the absence of high voltages, cathode nodes etc.

The technical result is achieved by the fact that the plasma bremsstrahlung generator contains a microwave resonator placed in a magnetostatic field of the plug configuration, pulsed magnetic coils are placed on the microwave cavity in the interpole space of the electromagnet, which provide additional electron acceleration in the autoresonant mode to relativistic energies and the generation of bremsstrahlung during interaction accelerated electrons with a solid target outside the formation zone bottom of the plasma in the resonator, and / or with a gas target formed by a pulsed gas valve connected to the resonator, creating a gas jet directed to the localization region of the accelerated electron bunch.

The fundamental possibility of generating x-rays in a wide range of wavelengths was shown in [17–20]. The basis of such a generation is the physical processes of ECR interaction, as well as the production of plasma relativistic formations in the mode of gyromagnetic autoresonance (GA). In this mode, the resonance condition is automatically self-supported due to an increase in the relativistic mass of plasma electrons trapped in the acceleration mode due to a quasi-synchronous increase in the magnetic field. This creates a long-lived relativistic electron bunch held by a magnetic field, the radius of rotation of which is close to the radius of the entire plasma formation.

Thus, the proposed device for generating bremsstrahlung x-rays contains a plasma bunch held in the magnetic field of the plug configuration, formed as a result of an original autoresonant method for accelerating plasma electrons to relativistic energies, similar to [21]. X-ray generation occurs during the interaction of a bunch of accelerated electrons with a solid-state and / or gas target.

It should be noted that in the proposed device can be implemented various methods of creating a population of energetic electrons, both during ECR interaction, similar to the prototype [9-16], and in the GA mode [17, 21], which can be widely used for applied purposes .

The design of the device and its operation is illustrated in figures 1-4. The scheme of the claimed device is shown in Fig. 1. The distribution of the magnetic field along the axis of the device in time is shown in Fig. 2. Figure 3 shows the relative position of the microwave pulses and the pulsed magnetic field in time. Figure 4 shows the time course of the processes in a pulse-periodic mode.

The device is an axisymmetric system (see Fig. 1), in which a vacuum (10 ^-4 -10 ^-5 Torr) high-frequency resonator 2 filled with a plasma-forming gas (for example, inert) and pulsed magnetic field are placed in the interpolar space of the electromagnet 1 3 representing a single unit; To generate x-ray radiation, a solid-state target 4, located outside the heating zone, and / or a pulsed gas valve 5 is used.

The device operates as follows: an electromagnet 1 creates in the interpolar space a stationary magnetic field of a plug configuration; the flowing pulsed current in the coils 3 creates an additional pulsed reversible magnetic field, which reduces the resulting magnetic field to a value corresponding to the resonant value; at the same moment, the resonator 2 is pulsedly fed from the microwave generator, a gas breakdown is carried out, the cavity is filled with the original plasma and the electrons are captured into autoresonant acceleration mode; in the process of restoring the resulting magnetic field to the original one, the electrons of the initial plasma are simultaneously affected by the electric field of the electromagnetic wave and the magnetic field increasing in time; upon reaching the initial value of the magnetic field corresponding to the value of the stationary magnetic field, the microwave pulse is turned off; in this case, a bunch of accelerated electrons is concentrated in the central section of the resonator with a radius of rotation corresponding to the position of the target 4, which leads to the conclusion of the bunch on the target and the generation of x-ray radiation; To increase the radiation intensity, a pulsed gas valve 5 can be used, which provides a pulsed input of a powerful gas jet into the region of localization of the bunch.

The magnetic field of the device (Fig. 2) is a superposition of the stationary and pulsed (reverse) fields of the plug configuration. This configuration is provided for long-term retention of the created plasma formations in the working volume of the resonator. The temporal profile of the magnetic field is shown in Fig. 2: 6 is the initial profile of the stationary magnetic field (at the initial moment of time), 5-1-5 the profile of the resulting magnetic field (stationary and reversible pulsed field).

A high-frequency electric field, the intensity vector of which is oriented perpendicular to the magnetic induction vector, is created using a tunable TE ₁₁₁ cylindrical resonator.

The entire device operates in a pulse-periodic mode. The mutual arrangement of microwave pulses and a pulsed magnetic field in time is shown in Fig. 3.

The inventive device operates as follows: under starting conditions, the value of the stationary magnetic field with the value of the magnetic field strength in the geometrical center of the trap significantly exceeds the value required for ECR interaction, at time t ₁ (Fig. 3), a pulsed magnetic field is turned on, which reduces the field strength in the center of the trap to a level that provides ECR interaction (process 6-1, Fig. 2); at time t ₂ (Fig. 3), a pulsed microwave generator is turned on. Upon reaching conditions close to resonance, i.e. when the magnetic field value in the center of the resonator, at which the electron cyclotron frequency ω _se coincides with the frequency of the pump wave ω (microwave frequency), as a result of breakdown, the trap is filled with a low-temperature plasma within the working volume of the resonator (interval t ₂ -t ₃ , Fig. 3 ); either an external plasma injector is used; the influence of a pulsed magnetic field and an electromagnetic microwave field ensure the capture of the electrons of the initial plasma in the GA mode (Fig. 3); in the time interval t ₃ -t ₄ (Fig. 3), plasma electrons are accelerated to relativistic energies in the GA mode and the initial profile of the stationary magnetic field is restored (6, Fig. 2); in the time interval (4–15, the bunch is discharged onto the target and / or the gas is pulsed into the localization region of the bunch (Fig. 3), which leads to the generation of a powerful x-ray pulse. Fig. 4 shows the time course of the processes in a pulse-periodic mode.

The maximum achievable level of electron energy in GA is determined by the magnitude of the magnetic induction, achievable within the duration of the microwave pulse.

To increase the quantum yield of radiation, a pulse high-speed valve is used in the device to create a gas stream localized in space, which ensures the injection of neutral atoms into the confinement region of the relativistic plasma bunch.

The interaction of a plasma bunch with a target (solid state and / or gas) in order to generate x-ray radiation is ensured by:

- the movement of the relativistic plasma bunch along the radius and its output to the target;

- pulse inlet of a gas jet into the region of confinement of a plasma clot.

These methods make it possible to quickly and efficiently bring a bunch to a target located outside the zone of electron capture and acceleration.

The plasma-forming gas must provide efficient ignition of the discharge (i.e., have a low ionization potential). In addition, to reduce plasma losses on the walls of the vacuum chamber, the gas must have a large atomic mass. Inert gases such as argon, krypton or xenon are suitable gases in this regard. It is possible to use third-party injection, which ensures filling of the trap with plasma with a density below the critical frequency for the pump wave.

For effective processes of plasma creation and subsequent capture of electrons of the plasma bunch in the GA mode, a microwave generator power of ~ 1 kW is sufficient.

At a maximum electron energy of 500 keV, the electron current in the bunch upon capture of 10 ⁹ particles in the GA mode will be 60 mA, which effectively corresponds to an electric power of about 30 kW. At 10% efficiency, the conversion of electric power to X-ray power is about 3 kW, which is enough for most practical applications.

Along with the spectrum and radiation intensity, the dimensions of the source are an important consumer parameter of the x-ray source. The linear dimensions of a technically feasible device do not exceed 50 × 50 × 50 cm.

Thus, in comparison with the prototype of the claimed device allows to expand the working spectral range, significantly increase the radiation power and ensure its directivity.

Sources of information taken into account when preparing the application:

1. United States Patent # 4,553,256, Dec.13, 1982 K.G. Moses. Apparatus and method for plasma generation of X-ray bursts.

2. N. A. Uckan et al. Physics of hot electron rings in EBT: Theory and Experiment, ORNL / TM-7585, NTIS. 1981, pp. 1-4.

3. A.F. Popkov, V.I. Kargin et al. Plasma X-ray Radiation Source. Journal of X-ray Science and Technology, 5, 289-294, 1995.

4. United States Patent # 3,946,236, Mar. 23, 1976, T. G. Roberts et al. Energetic electron beam assisted X-ray generation.

5. Patent RU No. 2253194 dated 10.26.2000 Partloo V., Fomenkov IV, Oliver I., Ness R., Birks D. A radiation source based on a plasma focus with an improved pulsed power system.

6. Patent RU No. 2393581 dated 10.28.2008 Novikov G.K., Smirnov A.I., Markova G.V., Novikov V.G., Novikova L.N. A gas discharge device is an x-ray source.

7. Patent RU No. 2342810 dated 05.17.2007 Bogolyubov EP, Golikov AV, Dulatov AK et al. Plasma source of penetrating radiation.

8. Patent RU No. 2214018 of 06.22.2001 Schelkunov G.P. X-ray emitter.

9. United States Patent # 5,323,442, Jun.21, 1994 K.S. Golovanivsky et al. Microwave X-ray source and methods of use.

10. United States Patent # 5,355,399, Oct. 11, 1994 K.S. Golovanivsky et al. Portable X-ray source and method for radiography.

11. United States Patent # 5,577,090, Nov.19, 1996 K.G. Moses. Method and apparatus for product X-radiation.

12. United States Patent # 6449338 10/09/2002, Bacal Verney, Marthe (Paris, FR) et al. X-ray source and use in radiography.

13. T.J. Castagna, J. L. Schhet, D. D. Denton, N. Hershkowitz. X-rays in electro-cyclotron-resonance processing plasmas Appl. Phys. Lett. 60 (23), 8 June 1992, 2856.

14. K.S. Golovanivsky, V.D. Dougar-Jabon and D.V. Reznikov. Proposed physical model for very hot electron shell structures in electron resonance-driven plasmas Physical Review 1995, E 52, 2969.

15. S. V. Golubev et al. Soft x-ray Emission from millimeter-wave Electron Cyclotron Resonance Discharge. Journal of x-ray Science and technology 6, pp. 244-248 (1996).

16. B.B.Andreev, A.A. Balmashnov, A.M. Umnov et al. ECR plasma as a source of x-ray radiation: experiment and numerical simulation Izvestiya Akademii Nauk, physical series. 2003, t. 67. No. 9. S.1314-1321.

17. V.V. Andreev, K.S. Golovanivsky. An experiment on ECR in a magnetic field which is growing in time. Physics Letters 1984 v. 100A, p. 357-359.

18.V.V. Andreev, K.C. Golovanivsky. Plasma Synchrotron ZhIRAK-0 Plasma Physics 1985 t.11, 3, pp. 300-306.

19. V.V. Andreev, A.M.Umnov. Experiments with relativistic plasma produced by a microwave discharge in time de pendent magnetic field. Physica Scripta 1991, 43, p. 490-494.

20. V.V. Andreev, A.M. Umnov. Relativistic plasma and electron bunches in plasma synchrotrons of GYRAC. Plasma Sources Sci. Tech. 8 (1999) p. 479-487.

21.V.V. Andreev, K.S. Golovanivsky. The method of heating the plasma to relativistic temperatures Copyright certificate: No. 1322962, March 8, 1987.

Claims (1)

A plasma bremsstrahlung generator containing a microwave resonator placed in a magnetostatic field of a plug configuration with a small plug ratio and excited from a microwave generator, characterized in that pulsed magnetic coils are placed on the microwave resonator in the pole space of the electromagnet, and a pulsed gas valve is connected to the resonator, providing the formation of a powerful gas jet directed to the region of formation of a bunch of accelerated electrons, and outside the zone a solid-state target of small linear dimensions is installed in the resonator.

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