RU2754826C1 - Method for forming proton beams under atmospheric pressure - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to the field of forming charged particles under atmospheric pressure and can be used in scientific activities, in medicine, in technological processes, in secondary ion mass spectrometry under atmospheric pressure, wherein the use of proton beams containing up to 1012protons per second is possible. The method is characterised by the use of an electrolyte in form of a water-alcohol solution with the addition of an acid to a concentration of 0.1 M. Protons are extracted from the top of the electrolyte meniscus, wherein the electrolyte is in a non-homogeneous constant electric field. The proton extraction mode is stable for the entire duration of the electrolyte entering the meniscus.EFFECT: provided is possibility of obtaining a reproducible long-term stable proton current under atmospheric pressure.1 cl, 4 dwg

Description

The present alleged invention relates to the field of formation of charged particles at atmospheric pressure and can be used in scientific activities, in medicine, in technological processes, in secondary ion mass spectrometry at atmospheric pressure, in solving problems of organic and bioorganic chemistry, immunology, medicine, diagnostics diseases, biochemical research, pharmaceuticals, analyzes in proteomics, metabolomics and forensics, in which it is possible to use proton beams containing up to 10 ¹² protons per second. The invention relates to a new method for producing a proton beam. Traditionally, the production of a proton beam belonged to the field of vacuum electronics and accelerator technology, where a high vacuum is a prerequisite.

The method of obtaining a proton beam [1] is based on the implementation of the nuclear reaction ³ He (D, P) ³ He by bombarding a helium target containing ³ He in Ti with accelerated deuterium ions. Deuterium ions are obtained in an electric discharge in the cathode-anode gap of the ion source, the resulting ions are accelerated by a high voltage towards the helium target and excite a nuclear reaction ³ He (D, P) ³ He with the formation of protons, the energy of which is 15 MeV. A helium target is obtained by saturating Ti with tritium to the maximum concentration, followed by holding for up to 10 months and further separating tritium from Ti when heated to 400-500 ° C with continuous vacuum pumping. All ³ He formed as a result of the decay of tritium remains in Ti, and tritium is completely released. Due to the low penetrating power, only 5-6% of the total amount of the generated protons can be used when using a thin-walled outlet window.

The disadvantages of this method of obtaining a proton beam are: the need for vacuum pumping out of the proton generator housing, long-term preparation of the helium target and its long-term heating to 400-500 ° C, to implement a nuclear reaction, it is necessary to use hydrogen isotopes - tritium and deuterium, high energy of deuterium ions to carry out nuclear reactions with the maximum possible yield of protons, the need for a thin-walled exit window and, as a consequence, the loss of protons in the beam. All of the above disadvantages of the considered method of obtaining protons lead in the future to an overall and complex implementation.

The considered method has much in common with another [2, 3] method, in which protons are obtained directly in an electric discharge in a stream of hydrogen. To form a proton beam and increase the density of the ion current of protons and the density of the electron current of the discharge, a magnetic field oriented along the axis of the hydrogen ion source is used, which compresses the diameter of the discharge channel several times and, accordingly, increases the proton current output from the ion source. The disadvantages of this method for producing protons include: the presence of an evacuated vacuum chamber in which the gas-discharge ion source is located, the sputtering of the source electrodes under the influence of the discharge, and, accordingly, the presence of foreign ions of the electrode material in the proton beam, while maintaining the operating mode of the ion source requires displacement of the rod cathode along the axis, only the pulsed mode of proton generation.

The method of forming a proton beam without using hydrogen ionization in an electric discharge [4] is selected as a prototype in this patent.

The known method consists in the fact that protons from the electrolyte contained in the proton accumulator, under the action of an electric field, diffuse through the palladium anode to the surface facing the vacuum. From the anode surface, under the action of the electric field of another grid electrode, protons are emitted into vacuum in the form of a proton beam, and then are accelerated under the action of the cathode potential.

The disadvantages of this method are the need for a vacuum chamber, the use of specific materials for the implementation of the method, in particular, palladium for the anode, a composite material adsorbing hydrogen, a material with high electrical conductivity for hydrogen ions.

The purpose of the proposed method is to obtain protons at atmospheric pressure under normal conditions, based on the fact that from the electrolyte, which is a water-alcohol solution with the addition of acid to a concentration of not more than 0.1 M, there is a drop-free extraction of protons into the atmosphere in a strong inhomogeneous electric field from the top of the meniscus of the solution located at the end of the capillary with subsequent separation of the proton flux from heavy charged particles at atmospheric pressure.

Experimental verification showed that during electrospray of aqueous-alcoholic solutions by the claimed method (drip-free spraying mode), a long-term stable proton current was obtained, while no solution jet was injected from the top of the meniscus, and no droplets appeared on the counter electrode. The lifetime of a stable drip-free mode of electrospray is determined by the time of supply of an aqueous-alcoholic solution with the addition of acid to the required concentration to the apex of the meniscus. Figure 1 shows the dependence of the stability of the proton current when spraying a water-alcohol solution with the addition of formic acid to a concentration of 0.1 M. (figure 2), with 0.1% addition of acid in the solution - the jet of microdroplets is absent (figure 3) and with 1% addition of acid - the jet of microdroplets is absent (figure 4).

In favor of the emission of protons from an aqueous solution of an organic volatile solvent with the addition of acid up to 0.1 M is the fact that with an increase in the concentration of acid in the solution at the top of the meniscus of the solution, an electrical breakdown of the gas (air under normal conditions) occurs, which does not occur during electrospray -alcoholic solution of KCl at a concentration of 0.5 M. Taking into account the anomalous mobility of protons both in liquid and in gas, which is 3.5-5 times higher than the mobility of other particles, it is logical to assume the existence of free protons in the atmosphere with this method of their emission. To implement the proposed method for producing proton beams at atmospheric pressure, it is possible to use any of the devices described in [5-10], based on the operating modes of the electrospray device with solutions with dynamic division of the flow of the sprayed liquid and the removal of its excess from the spray area under normal conditions. The resulting ion flux is converted from a diverging into a parallel axisymmetric flux of the required diameter [11] and then impulsively separated from heavy charged particles at atmospheric pressure [12] with further transportation of the proton flux by a system of diaphragms with a distributed constant voltage [11].

Sources of information

1. USSR author's certificate No. 353282 dated 09.29.1972. Proton generator. A.M. Rodian, V.V. Surenyants, I.T. Sidorov, A.T. Davydov.

2. RF patent No. 2098883 from 10.12.1997. Pulsed proton source with a cathode cone. Lapitsky Yu.Ya.

3. RF patent №2249880 from 24.06.2003. Pulsed hydrogen ion source with cold bar cathode. Lapitsky Yu.Ya.

4. RF patent No. 2393578 dated 11/13/2008. A source that forms a proton beam. Chervonobrodov S.P.

5. RF patent №2608361 dated January 18, 2017. Device for the formation of a drop-free ion flow during electrospray of analyzed solutions in ion sources with atmospheric pressure. M.N. Krasnov, N.V. Krasnov.

6. RF patent No. 2530783 dated 15.08.2014. Device for electrospraying chromatographic streams of analyzed solutions of substances for ion sources. M.Z. Muradymov, V.A. Samokish, N.V. Krasnov.

7. RF patent Utility model No. 169146 dated 03/07/2017. The device of an ion source-electrospray for obtaining a drop-free stable ionic current of analytes from solutions for a long time. Krasnov M.N., Krasnov N.V.

8. RF patent No. 2587679 dated 05/27/2016. Device for continuous stable electrospraying of solutions in an ion source at atmospheric pressure. M.Z. Muradymov, S.Yu. Semenov, N.V. Krasnov.

9. RF patent No. 2608361 06/04/2015 A device for the formation of a drop-free ion flow during electrospray of the analyzed solutions in ion sources with atmospheric pressure. M.N. Krasnov, N.V. Krasnov.

10. RF patent №2608362 06/11/2015 Stable electrospray device at atmospheric pressure of solutions of substances for ion sources. M.Z. Muradymov, O. V. Pashkov, N.V. Krasnov.

11. A.N. Arseniev, I.V. Kurnin, N.V. Krasnov, M.Z. Muradimov, T.V. Pomozov, M.I. Yavor, M.N. Krasnov. Optimization of ion transport from atmospheric pressure ion sources. International Journal for Ion Mobility Spectrometry, 2019, V. 22, No. 1, P.31-38 DOI: 10.1007 / s 12127-018-02420-2.

12.Application No. 2019124208. The decision to issue a patent dated 02.17.2020. Method for preliminary separation of charged particle flux in ion sources with ionization at atmospheric pressure. Krasnov N.V., Muradymov M.Z., Krasnov M.N., Kurnin I.V.

Patentee:

Federal State Budgetary Institution of Science IAL RAS (RU) Limited Liability Company Device Consulting (RU) Authors: Krasnov Nikolay Vasilievich (RU), Krasnov Maxim Nikolaevich (RU), Muradymov Marat Zarifovich (RU), Kurnin Igor Vasilievich (RU) ...

Claims (1)

A method for producing proton beams at atmospheric pressure, based on the fact that the extraction of protons and their transportation from the electrolyte volume occurs through the membrane microchannels into the space with a constant electric field, characterized in that from the electrolyte, which is an aqueous solution of a highly volatile organic solvent with the addition of acid to a concentration no more than 0.1 M, protons are extracted in a strong inhomogeneous electric field from the top of the meniscus of the solution located at the end of the capillary, followed by the conversion of the flow of charged particles from diverging to parallel, by impulse separation of the proton flow from heavy charged particles and further transportation of the proton flow by the diaphragm system at atmospheric pressure.

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