RU2513206C1 - Method of separating thorium-228 and radium-224 - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to radio chemistry and can be used in producing a radium-224 reparation and a pure thorium-228 preparation used in nuclear medicine. The method involves dissolving starting material containing thorium-228 and radium-224 in HCl to obtain a first solution containing ThCl₄, RaCl₂ and free HCl, and a second solution containing RaCl₂ and NaCl. The first solution is treated with sodium hydroxide to form Th(OH)₄ particles. The second solution is treated with sodium carbonate to form RaCO₃ particles and an end solution containing NaCl. The solutions are treated in the presence of fibrillated cellulose fibres in each solution. The preparations are extracted from the solutions, wherein the thorium-228 preparation is extracted from the second solution before treatment thereof.

EFFECT: obtaining sorption products in form of dispersions consisting of second and end solutions and composite preparations consisting of cellulose fibres with Th(OH)₄ and RaCO₃ particles strongly immobilised thereon.

3 cl

Description

The invention relates to radiochemistry and can be used to obtain used in nuclear medicine, the preparation of radium-224, as well as the preparation of pure thorium-228.

A known method of producing a preparation based on radium-224 from its mixture with thorium-228 (RU, 2441687, B01D 15/08, G21G 4/08, publ. 20.10.2011). The method includes preparing from the starting material a first solution of thorium-228 and radium-224 in a 3-4 M hydrochloric acid solution, selective sorption of thorium-228 by the ion-exchange mechanism from this solution in a column on a phosphonic acid cation exchange resin to obtain a sorption product in the form of a composite preparation consisting of ion exchange resin with thorium-228 immobilized by it in the form of its ions, keeping this material for four or more days to accumulate radium-224 in it in an amount of at least 50% of its equilibrium amount. Radium-224 formed on the cation exchange resin as a result of the decay of thorium-228 is desorbed with a 7-8M hydrochloric acid solution. The radium-224 solution thus obtained was passed through an ion exchange column to remove inactive cations, then it was evaporated to dryness and the residue was dissolved in a 1 M nitric acid solution to obtain a second solution containing Ra (NO ₃ ) ₂ . This solution is passed through a cation exchange resin column and a sorption product is obtained in the form of a composite material consisting of an ion exchange resin with radium-224 immobilized by it in the form of its ions. Next, the sorbed radium-224 is desorbed with an 8M solution of nitric acid. The desorbate containing radium-224 is evaporated to dryness and the residue is dissolved in a predetermined volume of nitric or hydrochloric acid to obtain the final product.

Other products of the process of obtaining a preparation based on radium-224 are acidic solutions that are forbidden to be discharged into the sewer, which are formed at the stages of ion-exchange sorption of thorium-228 and radium-224, one of which contains radium-224 in an amount equal to its content in the original (first ) solution.

Information about the fate of these solutions in the description of the method is not contained.

The disadvantages of the method are its great complexity, the need to use expensive selective ion-exchange materials, the formation of wastewater to be decontaminated, as well as the frequency of its implementation.

New technical results from the use of the invention are the simplification of the method, the elimination of the use of ion-exchange materials, the complete separation of thorium-228 and radium-224, the preparation of preparations in a convenient form for use, the reduction of thorium and radium in the final solution to a level not exceeding the limits of dissolution Th (OH) ₄ and RaCO ₃ , as well as providing the possibility of carrying out the separation process in a continuous mode.

These results are achieved in that in a method for the separation of thorium-228 and radium-224, which includes stages in a given sequence of dissolving them in HCl of a starting material containing thorium-228 and radium-224, to obtain a first solution containing ThCl ₄ , RaCl ₂ and free HCl, holding thorium-containing material for a time sufficient for the formation of radium-224 in it in an amount equal to at least 50% of the equilibrium amount, sorption of thorium-228 from the first solution, obtaining a second solution, sorption of Ra-224 from the second solution, s education on adia of sorption of its products in the form of composite preparations consisting of sorbents with thorium-228 and radium-224 immobilized by them, according to the invention, the starting material is maintained for a predetermined time, fibrillated cellulose fibers containing, in wt.%, not less than 50% of fibers with a length of not more than 0.14 mm and not less than 90% of fibers with a length of not more than 0.5 mm are converted into insoluble compounds before sorption of ThCl ₄ and RaCl ₂ by treatment of the first solution with sodium hydroxide to form Th (OH) particles ₄ and a second p alignment containing RaCl ₂ and NaCl, the processing of the second solution to form a sodium carbonate particles RaCO ₃ and the final solution containing NaCl, while the processing solution is carried out in the presence in each of said sorbent sorption onto the cellulosic fibers of said insoluble particles during their formation with obtaining sorption products as dispersed second solutions and the final composite products composed of cellulose fibers with a firmly immobilized on these particles Th (OH) ₄ and RaCO _3, followed by breeding reparative of solutions, the preparation of thorium-228 is outputted from the second solution prior to its processing. Cellulose fibers are contained in solutions during their processing in an amount of 50-150 mg / dm ³ , and thorium-228 and radium-224 preparations are removed from solutions by precipitation or pressure flotation.

Typically, the starting material to be processed to separate thorium-228 and radium-224 contains thorium-228 as the main component, and radium-224 as an impurity. Its content can range from a few percent relative to the equilibrium content, to an equilibrium amount. Accordingly, the exposure time of a particular sample of the starting material, sufficient to achieve, for example, 50% content relative to the equilibrium amount, can vary markedly.

It is advisable to use fibrillated cellulose fibers (PCV) with the above characteristics as the sorbent when extracting particles of insoluble thorium and radium compounds from the liquid phase, since they have a very high sorption capacity. For example, it can achieve, based on 100 parts by weight of fibers, 1000 and more parts by weight finely dispersed insoluble particles of compounds formed and sorbed on the fibers during their chemical deposition.

In addition, these fibers themselves, as well as composite materials consisting of such fibers with particles firmly sorbed by them, are capable of forming flocculi and flakes in the aquatic environment that are well floated to the surface of the water with the formation of stable flotation sludge, for example, during pressure flotation, without the use of auxiliary substances, such as flocculants, coagulants, flotation agents.

These composite materials are also well deposited. The precipitate is dehydrated by known methods much easier than the precipitate without FCV.

The solubility product of thorium hydroxide is several orders of magnitude smaller than the solubility product of radium hydroxide. Therefore, when processing the initial (first) solution with sodium hydroxide at a flow rate not exceeding stoichiometrically equal to the content of free acid and thorium in the solution, this reagent is completely and exclusively spent on neutralizing the acid and on the reaction with thorium ions to form insoluble hydroxide from its entire amount.

The method is as follows. The first solution is prepared by dissolving the starting material in hydrochloric acid. A suspension of FCV is also prepared. In the first mixer serves the first solution containing ThCl ₄ , RaCl ₂ and HCl, as well as a suspension of PCV at the rate of, for example, 50 mg of fibers per dm ^{3 of the} solution. The resulting dispersion is fed into a first flow reactor, to which a predetermined amount of NaOH solution is also fed. As a result of chemical reactions and the sorption process, a dispersion is formed in the reactor from a composite preparation of thorium-228, consisting of PCV with Th (OH) ₄ particles firmly immobilized by them, and a second solution containing RaCl ₂ and NaCl. The dispersion is sent to the first saturator, to which air is also supplied under excess pressure. From the saturator, the air-saturated dispersion is fed under pressure to the first flotator, in the chamber of which, when the pressure is relieved to normal, the particles of the drug are flotted by small air bubbles released from the water to the surface of the water and the formation of a slurry. The sludge is recycled, and the clarified solution is fed into a second mixer, to which a predetermined amount of PCV is also fed (for example, 150 mg of fibers per dm ³ ) and a suspension of PCV in a second solution is obtained. It is sent to a second reactor, to which sodium carbonate solution is also supplied in an amount stoichiometrically equal to the content of Ra-224 ions in the solution. As a result of the chemical reaction and the sorption process, a dispersion is formed in the reactor containing a composite preparation of radium-224, consisting of PCV with RaCO ₃ particles firmly immobilized by them. The liquid phase contains only NaCl. The dispersion is sent to a sump or to a second saturator and from it to a second flotator. In any case, the composite preparation isolated from the liquid phase is sent for processing.

Processing includes washing, thickening sludge or sedimentation on a press filter or using a centrifuge, washing and drying thorium and radium preparations. The liquid phases from the thickening and washing of the thorium-228 preparation are returned to the second solution. The drug radium-224 can be treated with hydrochloric or nitric acid and get a solution of radium of a given concentration.

The preparation of thorium-228 can be used as a “donor" to obtain pure preparations of radium-224. For this, the thorium preparation is kept for a predetermined time and extracted with a predetermined amount of water. Radium-224 hydroxide, with significant solubility, is transferred to the extract. Next, this solution is treated with sodium carbonate in the presence of FCV and receive the preparation of radium-224 in the form of particles of RaCO ₃ sorbed on FCV.

All possible options (examples) of using the method are carried out in full accordance with the general description. A change in the concentration of PCV in solutions in the range of 50-150 mg / dm ³ practically does not change anything.

Claims (3)

1. The method of separation of thorium-228 and radium-224 involves dissolving in HCl a starting material containing thorium-228 and radium-224 to obtain a first solution containing ThCl ₄ , RaCl ₂ and free HCl, its treatment with sodium hydroxide to form Th particles (OH) ₄ and a second solution containing RaCl ₂ and NaCl, treatment of the second solution with sodium carbonate to form particles of RaCO ₃ and the final solution containing NaCl, while the solutions are treated in the presence of fibrillated cellulose fibers containing, in wt. .%, not less than 50% of fibers with a length not more than 0.14 mm and not less than 90% of fibers with a length of not more than 0.5 mm with sorption on the cellulose fibers of these particles during their formation to obtain sorption products in the form of dispersions consisting of the second and final solutions and composite preparations consisting of cellulose fibers with particles of Th (OH) ₄ and RaCO ₃ firmly immobilized on them, followed by the removal of preparations from solutions, and the thorium-228 preparation is removed from the second solution before treatment. 2. The method according to claim 1, characterized in that the cellulose fibers are contained in solutions during their processing in an amount of 50-150 mg / dm ³ . 3. The method according to claim 1, characterized in that the preparations of thorium-228 and radium-224 are removed from solutions by precipitation or pressure flotation.