Dissolution of uranium from phosphorite by different solutions Текст научной статьи по специальности «Биологические науки»

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YflK 65.011.1:622.012

DISSOLUTION OF URANIUM FROM PHOSPHORITE BY DIFFERENT SOLUTIONS

A. Minjigmaa, G. Oyun-Erdene, D. Enkhtuya*, G. Amgalan, Zh.G. Bazarova**^**, B. Darkhijav

Institute of Chemistry and Chemical Technology, Mongolian Academy of Science, Ulaanbaatar University of Railway, Mongolia, Ulaanbaatar **Baikal Institute of Nature Management SB RAS, Ulan-Ude Buryat State University, Ulan-Ude

The world average uranium content in phosphate rock is estimated at 50-120 g/tn. The U concentration ranges 10-27 g/tn in Mongolian phosphate deposits. The aim of this study is to improve quality of the activated phosphorus fertilizer. We decreased uranium concentration from 12g/tn till 3.9 g/tn in the milled phosphate raw by carbonate and citric acid solutions. This work demonstrated that sodium carbonate/bicarbonate uranium leaching process is selective and effective to extract 67,5% of uranium from Burenkhaan phosphate rock.

Key words: uranium, phosphate.

The phosphate is main source of fertilizer and about 95% of the world total phosphate rock production used in agriculture as fertilizers, pesticides and animal feeds. Phosphate rock used for fertilizer contain trace amounts of radioactive elements such as a uranium, K40 and thorium. The world average uranium content in phosphate rock is estimated at 50-200 ppm or 0.005-0.020%. Phosphate rock containing up to 120 ppm uranium have been used as a source of uranium fuel. Few data exists on uranium accumulation in soils and uranium plant uptake from phosphate fertilization [1]. No increase in soil and plant uranium was detected in a long term experiment with triple superphosphate fertilization [2]. However, as these authors stated, considering the mobility of U6+ (uranyl ion), it is hardly surprising that no uranium accumulation was found in soil, rather, these results imply that uranium applied with the phosphate fertilizer had leached into the ground water that drained from the fields. Increased uranium concentrations in surface and ground water and water from drainage channels after long term mineral fertilization have been reported [3-5].

Marine phosphorite deposits contain averages of 6-120 ppm, and organic phosphorite deposits up to 600 ppm [6] phosphate rock of sedimentary-type contains an appreciable amount of uranium in the range of

0.005-0.03% U3O8 in isomorphous substitution for Ca [7-8]. The phosphate rock deposits of USA, North Africa, Israel, Jordan and Morocco etc., contain an average U content of 0.01-0.02% U3O8 [9]. The uranium concentration ranges from 0.0001 to 0.0027% in Mongolian phosphate deposits. The concentrations were in the Burenkhaan - 0.0027%, in Alagiin Davaa, Tsakhir-Uul - 0.0001% and in Mankhan-Uul - 0.0001% [10]. It is clear that Mongolian phosphate rock average uranium concentration was lower than the world average

uranium concentration (0.005%). About 6.34 million tones of uranium exists in rock phosphate deposits throughout the world [11]. Uranium occur tetravalent (U4+) and hexavalent (U6+) oxidation states in the phosphate [12].

The aim of this study is to decrease concentration of uranium from phosphate rock by citric acid and carbonate solutions, which improves quality of the activated phosphorus fertilizer.

Materials and methods

The rock phosphorite samples was obtained from the Burenkhaan deposit, Khuvsgul Phosphate Basin, Mongolia. The phosphate rock contain 35% P2O5 and samples were ground with different particle sizes (0.05, 0.075, 0.125, 0.175 and 0.2 mm). X-ray diffraction was used to determine the mineralogical composition of the phosphorite. The uranium concentration determined by the gamma-spectrometer.

Results and discussion

Chemical composition of the phosphate

The Burenkhaan phosphorite sample was analyzed, characterized by chemical analysis and X-ray diffractometer. Table 1 shows the composition of phosphorite from Burenkhaan deposit, Northern Mongolia. By [1] phosphorite classification Burenkhaan raw sample belongs to the reach phosphorite (P2O5-35%). CaO dominated in the phosphorite and average concentration of CaO was 45.8% in studied sample. It is clear that Burenkhaan phosphorite sample is fluorapatite. Also concentration of the fluorine was higher in Burenkhaan than Alagiin Davaa, Thakhir-Uul and Mankhan-Uul phosphate deposits. There is positive correlation between concentration of P2O5 and CaO, whereas SiO2 was negatively correlated.

Table 1.

Main chemical composition of Burenkhaan phosphate

- in O <N P CaO O Ml 2 m o <N < m o <N e (Jh O <u pH <N O & MnO O <N CG £ K2O m o 2 o £ Ph * * O L W

Bkh* 35.0 45.8 0.84 0.76 0.97 0.1 4.4 0.01 0.4 0.1 <0.1 8.36 2.41 2.05 101.4

* - Phosphorite from Burenkhaan deposit; ** - Loss of Ignition

1 D ■ Ca^POJjF, Fluoiapatite

£ I'SiOj, Quartz 9

1 1

0- i i i i | i i i i | i i i i | i i i i | i i i i | i i i i | i i i i | i i i i | i i i i | i i i i | i i i i | i i i i | i i i i | i i i i

10 20 30 « SO * 30 if

Pic. 1. X-ray diffractogramm of the phosphate from Burenkhaan deposit

The XRD data for the finely ground phosphate shown by pic. 1. The fluorapatite was identified as a main phosphorus-containing mineral. X-ray analysis identified Burenkhaan phosphorite main minerals -quartz and hydrogen carbonate phosphate (pic. 1). Quartz mineral represent the main component, which is chracterized by diffraction lines 26.5, 20.9 and 50.1 A. The reflection of hydrogen carbonate phosphate appeares at 2a = 24.3, 29.2, 32, and 34.2 A .

Uranium leaching study

We dissolved uranium from phosphate by different solutions.

1. Uranium dissolution from phosphate in carbonate solutions

The leaching experiments were carried out in 1L Erlenmeyer flasks. 100 g of each phosphate milled samples were treated 500 ml different concentrations of 0.1 M sodium bicarbonate (250 ml) and 0.5 M sodium carbonate solutions (250 ml) for 3 h at 60-70oC. Solutions ratio of carbonate and bicarbonate was 1:1. The reaction will goes as follow:

2UO2+O2=2UOb UO3+Na2CO3+2NaHCOs=Na4UO2(CO3)3+H2O (Merritt, 1971)

2. Uranium dissolution from phosphorite in citric acid solution

100 g of each phosphate samples were treated 1000 ml 0.5 M citric acid (C6H8O7) solution. The uranium leaching reaction goes as follow:

(C6H8O7) « (C6H5O7)3-+3H+

2(C6H5O7f+3UO22+« (UO2)3+(C6H5O7)2

Table 2.

Uranium dissolution in different solutions

№ Solutions U g/tn Leaching rate (%)

1 Raw phosphate 12.0 -

2 Sodium carbonate (0.5M) 3.9 67.5

3 Citric acid (0.5M) 4.4 63.3

The result shows that concentration of U was 12 g/tn in the studied samples. After leaching experiment uranium concentration decreased from 12 g/tn till 3.9 g/tn and 4.4 g/tn (Table 1, pic. 1, 2). Uranium is typically recovered in acid circuits using citric acid, or in alkaline circuits using a sodium carbonate, bicarbonate mix. This work demonstrated that sodium carbonate/bicarbonate uranium leaching process is selective and effective to extract 67.5% of uranium from Burenkhaan phosphate rock. Uranium is appearing at lines 235 and 609 (pic. 1; 2). The intensities of U were 2431, 1697 in the raw phosphate and after U leaching reaction intensities are decreased till 235, 609, respectively.

500

400

300

200

100

0

400 650 900

channel

Pic. 1. Gamma spectrogram of the U leached phosphate

Pic. 2. Gamma spectrogram of the raw phosphate

Technolgical regime for U extract

Effect of particle size of phosphate to the U extract

Raw phosphate samples of different size dissolved in citric acid solution (Table 3). Raw phosphate U concentration was 12 g/tn. After the uranium extraction the raw phosphate U decreased till 4.6 g/tn. Concentration of the extracted Uranium depends on particle size of the phosphate. There is negative correlation between particle size and concentration of extracted U. When particle size decreased from 0.2 mm to 0.05 mm then concentration of uranium in the phosphate were increase from 4.6 g/tn till 10.2 g/tn (pic. 3). Therefore, most selective particle size of phosphate is 0.2 mm for the uranium extraction.

Effect of particle size to U extract

Table 3.

№ Particle size (mm) U g/tn

1 0.05 10.2

2 0.075 9.4

3 0.125 7.6

4 0.175 5.8

5 0.2 4.6

o

c

o „ V. C

fZ -m

c hS2

{U D

u

c

o

u

Effect of extraction time

The milled Burenkhaan phosphate samples were mixed with sodium 0.5 M carbonate/bicarbonate and

0.5 M citric acid solutions for 1, 2, 3, 4 and 5 h at 60-70oC (to aviod decomposition of carbonate and citric) using termostatic hot plate provided with magnetic stirrer.

Table 4.

Relation between extracted U concentration and extraction time

Solution Extraction time

1 2 3 4 5

Carbonate 5.0 5.3 3.9 5.2 6.0

Citric acid 5.2 6.2 4.4 6.0 6.9

Table 4 and pic. 4 show the effect of extraction time on concentration of extracted uranium. Concentration of exracted uranium is significantly depends on extraction time. The raw phosphorite U was 12 g/tn and it decreased till 3.9 g/tn at 3 h. After 3 h the soluble uranium concentration decreased rapidly (pic. 1). Extracted U concentration decreased till 6 g/tn at 6 h. It can be concluded that decomposed precipitation of part of uranium in the solution and to the presence of tetravalent uranium. Therefore optimal U extraction time was found to be 3 h.

Particle size (mm)

Pic. 3. Effect of particle size to U extract

0 12 3 4

Extraction time (hour)

Pic. 4. Relation between extracted U concentration and extraction time

Carbonate/bicarbonate solution is most selective solution for uranium extraction. By this study we removed 67.5% uranium from raw phosphorite. Concentration of the extracted Uranium significantly depends on particle size of the phosphorite. Most selective particle size of phosphate is 0.2 mm for the uranium extraction. The optimal extration time for uranium leaching is 3 h. After 3 hours the soluble uranium concentration decreased because of precipitaion of uranium.

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